Microbend-resistant optical fiber

ABSTRACT

Disclosed is an improved, single-mode optical fiber possessing a novel coating system. When combined with a bend-insensitive glass fiber, the novel coating system according to the present invention yields an optical fiber having exceptionally low losses. 
     The coating system features (i) a softer primary coating with excellent low-temperature characteristics to protect against microbending in any environment and in the toughest physical situations and, optionally, (ii) a colored secondary coating possessing enhanced color strength and vividness. The secondary coating provides improved ribbon characteristics for structures that are robust, yet easily entered (i.e., separated and stripped). 
     The optional dual coating is specifically balanced for superior heat stripping in fiber ribbons, with virtually no residue left behind on the glass. This facilitates fast splicing and terminations. The improved coating system provides optical fibers that offer significant advantages for deployment in most, if not all, fiber-to-the-premises (FTTx) systems.

CROSS-REFERENCE TO PRIORITY APPLICATIONS

This application is a continuation-in-part of International Patent Application No. PCT/US2008/082927 for a Microbend-Resistant Optical Fiber, filed Nov. 9, 2008, (and published May 14, 2009, as International Publication No. WO 2009/062131 A1), which itself claims the benefit of U.S. Patent Application No. 60/986,737 for a Microbend-Resistant Optical Fiber (filed Nov. 9, 2007), U.S. Patent Application No. 61/041,484 (filed Apr. 1, 2008) for a Microbend-Resistant Optical Fiber, and U.S. Patent Application No. 61/112,595 for a Microbend-Resistant Optical Fiber (filed Nov. 7, 2008). Each of the foregoing patent applications and patent application publication is hereby incorporated by reference in its entirety.

FIELD OF THE INVENTION

The present invention embraces optical fibers possessing an improved coating system that reduces stress-induced microbending.

BACKGROUND OF THE INVENTION

Fiber to the premises/business/home (i.e., FTTx) provides broadband data transfer technology to the individual end-user. FTTx installations, which are being increasingly deployed throughout the world, are making use of innovative, reduced-cost system designs to promote the spread of the technology. For example, fiber may be delivered in the last link by way of a microcable. Air-blown fibers provide another efficient model for delivering the link to the end-use terminus. There continues to be industry-wide focus on modes of deployment that overcome economic obstacles that impede fiber-based broadband solutions for data transmission to businesses and residences.

Cost-effectiveness is important, of course, for achieving successful FTTx systems. Reduced size for cables, drops, and structures for blowing are often critical, too. Installation of conduits suitable for traditional cable designs is often prohibitive in existing infrastructure. Thus, existing small ducts or tight pathways have to be used for new fiber installations. Low-cost and reduced-size requirements are driving in a direction that reduces protection for the optical fibers (i.e., away from conventionally robust, more bulky cable designs).

Glass designs are now available that offer reduced sensitivity to small bending radius (i.e., decreased added attenuation due to the phenomenon known as macrobending). These include trench-assisted core design or void-assisted fibers. Glass designs with lower mode field diameter are less sensitive to macrobending effects, but are not compatible with the G.652 SMF standard. Single-mode optical fibers that are compliant with the ITU-T G.652.D requirements are commercially available, for instance, from Draka Comteq (Claremont, N.C.).

Microbending is another phenomenon that induces added loss in fiber signal strength. Microbending is induced when small stresses are applied along the length of an optical fiber, perturbing the optical path through microscopically small deflections in the core.

In this regard, U.S. Pat. No. 7,272,289 (Bickham et al.), which is hereby incorporated by reference in its entirety, proposes an optical fiber having low macrobend and microbend losses. U.S. Pat. No. 7,272,289 broadly discloses an optical fiber possessing (i) a primary coating having a Young's modulus of less than 1.0 MPa and a glass transition temperature of less than −25° C. and (ii) a secondary coating having a Young's modulus of greater than 1,200 MPa.

Nonetheless, better protection against microbending is still needed to help ensure successful deployment in more FTTx applications. To this end, it is necessary to discover and implement new coating systems that better address the demands FTTx installations place on fiber and cable structures in a way that is commercially practical (i.e., cost-effective).

SUMMARY OF THE INVENTION

Accordingly, it is an object of the present invention to provide an optical fiber having an improved coating system that provides improved protection against stress-induced microbending.

It is another object to provide an improved coating system that can be readily mated with bend-insensitive optical fiber, as well as G.652-compliant fiber.

It is yet another object to provide an improved optical fiber coating system including a primary coating that possesses a low modulus to provide enhanced cushioning against lateral and axial stresses induced by external forces.

It is yet another object to provide an improved optical fiber coating system including a primary coating that possesses an exceptionally low glass transition temperature (TO that reduces temperature-induced stresses in unusually cold environments.

It is yet another object to provide an improved optical fiber coating system including a primary coating that possesses an improved curing rate.

It is yet another object to provide an improved optical fiber coating system including an ink-free secondary coating that has improved brightness and visibility.

It is yet another object to provide an improved optical fiber coating system that can be applied at commercial processing speeds (e.g., forming the primary coating at rates of at least about 20 meters per second).

It is yet another object to provide an optical fiber possessing coatings that are readily stripped.

It is yet another object to provide an optical fiber having enhanced performance characteristics for use in FTTx installations in which conventional, robust cable designs are impractical.

It is yet another object to provide an optical fiber that synergistically combines a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) with the coating according to the present invention (e.g., Draka Comteq's ColorLock^(XS) brand coating system).

It is yet another object to provide an optical fiber that can be advantageously deployed in buffer tubes and/or fiber optic cables.

It is yet another object to provide an optical fiber that requires less external protection (e.g., enclosed within thinner buffer tubes and/or cable jacketing).

It is yet another object to provide a bend-insensitive optical fiber possessing a reduced diameter (e.g., having thinner coating layers).

It is yet another object to provide an optical fiber that can be installed in a way that employs small-radius bends.

It is yet another object to provide an optical fiber that facilitates direct installation onto buildings or other structures (e.g., stapled or otherwise secured to structural surfaces).

The foregoing illustrative summary, as well as other exemplary objectives and/or advantages of the invention, and the manner in which the same are accomplished, are further explained within the following detailed description and its accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts microbend testing results demonstrating that exceptionally low microbending losses are achieved, in accordance with the present invention, by pairing a bend-insensitive glass fiber with a low-modulus primary coating.

FIG. 2 schematically depicts the relationship between the in situ modulus of a primary coating and added loss for a multimode optical fiber.

FIG. 3 depicts the dynamic mechanical properties of a typical commercial primary coating (i.e., a conventional primary coating).

FIG. 4 depicts the dynamic mechanical properties of an exemplary primary coating used in producing optical fibers according to the present invention.

FIG. 5 depicts microbend testing results for optical fibers that include a conventional primary coating and for optical fibers that include an exemplary primary coating according to the present invention.

FIG. 6 depicts microbend testing results (under rigorous temperature-cycle testing conditions) for optical fibers that include a conventional primary coating and for optical fibers that include an exemplary primary coating according to the present invention.

FIG. 7 depicts microbend testing results (under modified temperature-cycle testing conditions) for optical fibers that include a conventional primary coating and for optical fibers that include an exemplary primary coating according to the present invention.

FIG. 8 depicts microbend testing results demonstrating that exceptionally low microbending losses are achieved, in accordance with the present invention, by pairing a bend-insensitive glass fiber with a low-modulus primary coating.

FIG. 9 depicts microbend testing results (under rigorous temperature-cycle testing conditions) for conventional optical fibers and for optical fibers that, in accordance with the present invention, combine a bend-insensitive glass fiber with a low-modulus primary coating.

FIG. 10 depicts microbend testing results (under modified temperature-cycle testing conditions) for conventional optical fibers and for optical fibers that, in accordance with the present invention, combine a bend-insensitive glass fiber with a low-modulus primary coating.

FIG. 11 depicts attenuation (added loss) as a function of MAC number (i.e., mode field diameter divided by cutoff wavelength) for various exemplary optical fibers.

FIG. 12 depicts, on a logarithmic scale, microbend sensitivity as a function of MAC number (i.e., mode field diameter divided by cutoff wavelength) for various exemplary optical fibers.

FIG. 13 depicts bending losses at a wavelength of 1625 nanometers with a bending radius of 15 millimeters in a standard single-mode fiber (SSMF) versus the MAC value at the wavelength of 1550 nanometers.

FIG. 14 depicts the nominal refractive index profile of an exemplary single-mode fiber.

FIGS. 15 a, 15 b, and 15 c are graphs illustrating, for different bending radii, the bending losses at a wavelength of 1625 nanometers in relation to the MAC value at a wavelength of 1550 nanometers for different standard single-mode fibers (SSMF) and for different optical fibers.

FIGS. 16 a and 16 b are graphs illustrating losses through microbending.

FIG. 17 depicts the cross-section (not to scale) of an exemplary optical fiber.

FIG. 18 depicts the set profile of a step-index fiber.

FIG. 19 depicts bending losses at the wavelength of 1625 nanometers versus the bending radius for optical fibers.

FIG. 20 schematically depicts a cross-section (not to scale) of an exemplary optical fiber.

FIG. 21 a depicts a reference refractive index profile of an exemplary optical fiber.

FIG. 21 b depicts germanium dopant concentration in the exemplary optical fiber of FIG. 21 a.

FIG. 21 c depicts fluorine dopant concentration in the exemplary optical fiber of FIG. 21 a.

FIG. 22 depicts dispersion characteristics for four different kinds of optical fibers.

FIG. 23 depicts a cross section of a single-mode fiber with cladding layers at respective radii extending from the center.

FIG. 24 depicts the nominal refractive index profile of the exemplary single-mode fiber of FIG. 23.

DETAILED DESCRIPTION

In one aspect, the present invention embraces optical fibers possessing an improved coating system that reduces stress-induced microbending, even in exceptionally cold environments required for FTTx deployments. The coating system according to the present invention includes a primary coating that combines low in situ modulus (e.g., less than about 0.5 MPa as measured on the fiber) and low glass transition temperature (T_(g)) (e.g., less than about −50° C.) to reduce stresses caused by external force and temperature. In addition, the coating system can be processed at high production speeds (e.g., 15-20 msec or more).

The present invention achieves a microbend-resistant optical fiber, particularly a single-mode optical fiber, by employing as its primary coating a UV-curable, urethane acrylate composition. In this regard, the primary coating includes between about 40 and 80 weight percent of polyether-urethane acrylate oligomer as well as photoinitiator, such as LUCERIN TPO, which is commercially available from BASF. In addition, the primary coating includes one or more oligomers and one or more monomer diluents (e.g., isobornyl acrylate), which may be included, for instance, to reduce viscosity and thereby promote processing. A suitable composition for the primary coating according to the present invention is a UV-curable urethane acrylate product provided by DSM Desotech (Elgin, Ill.) under the trade name DeSolite® DP 1011. In this regard and as noted, U.S. Patent Application No. 60/986,737 for a Microbend-Resistant Optical Fiber (Overton), U.S. Patent Application No. 61/041,484 (Overton) for a Microbend-Resistant Optical Fiber, and U.S. Patent Application No. 61/112,595 for a Microbend-Resistant Optical Fiber (Overton) are hereby incorporated by reference in their entirety. Likewise, U.S. Patent Application Publication No. US 2009/0175583A1 and its related U.S. patent application Ser. No. 12/267,732 a Microbend-Resistant Optical Fiber (Overton) are hereby incorporated by reference in their entirety.

Suitable glass fibers for use in the present invention include glass fibers such as those disclosed in U.S. Pat. No. 4,838,643 for a Single Mode Bend Insensitive Fiber for Use in Fiber Optic Guidance Applications (Hodges et al.); U.S. Patent Application Publication No. US 2007/0127878 A1 and its related U.S. patent application Ser. No. 11/556,895 for a Single Mode Optical Fiber (de Montmorillon et al.), now U.S. Pat. No. 7,623,747; U.S. Patent Application Publication No. US 2007/0280615 A1 and its related U.S. patent application Ser. No. 11/697,994 for a Single-Mode Optical Fiber (de Montmorillon et al.); now U.S. Pat. No. 7,587,111; U.S. Pat. No. 7,356,234 and its related U.S. patent application Ser. No. 11/743,365 for Chromatic Dispersion Compensating Fiber (de Montmorillon et al.); U.S. Patent Application Publication No. US 2008/0152288 A1 and its related U.S. patent application Ser. No. 11/999,333 for an Optical Fiber (Flammer et al.); now U.S. Pat. No. 7,555,186; U.S. Patent Application Publication No. US 2009/0279835 A1 and its related U.S. patent application Ser. No. 12/436,423 for a Single-Mode Optical Fiber Having Reduced Bending Losses (de Montmorillon et al.); U.S. Patent Application Publication No. US 2009/0279836 A1 and its related U.S. patent application Ser. No. 12/436,484 for a Bend-Insensitive Single-Mode Optical Fiber (de Montmorillon et al.); U.S. Patent Application No. 61/101,337 for a Single Mode Optical Fiber (de Montmorillon et al.); U.S. Patent Application No. 61/112,006 for a Bend-Insensitive Single-Mode Optical Fiber (de Montmorillon et al.); and U.S. Patent Application No. 61/112,374 for a Bend-Insensitive Single Mode Optical Fiber (de Montmorillon et al.). Each of these commonly assigned patent documents is hereby incorporated by reference in its entirety. One exemplary glass fiber, for instance, possesses a step-index core having a refractive index that is between about 0.003 and 0.006 higher than the refractive index of its adjacent silica cladding.

Exemplary single-mode glass fibers for use in the present invention are commercially available from Draka Comteq (Claremont, N.C.) under the trade name BendBright®, which is compliant with the ITU-T G.652.D requirements, and the trade name BendBright^(XS)®, which is compliant with the ITU-T G.657.A/B and ITU-T G.652.D requirements.

In particular and as set forth herein, it has been unexpectedly discovered that the pairing of a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) and a primary coating having very low modulus (e.g., DSM Desotech's UV-curable urethane acrylate product provided under the trade name DeSolite® DP 1011) achieves optical fibers having exceptionally low losses (e.g., reductions in microbend sensitivity of at least 10× (e.g., 40× to 100× or more) as compared with a single-mode fiber employing a conventional coating system). Draka Comteq's bend-resistant, single-mode glass fiber available under the trade name BendBright^(XS)® employs a trench-assisted design that reduces microbending losses.

FIG. 1 depicts this outstanding result by comparing the aforementioned exemplary single-mode fiber according to the present invention with various single-mode fibers employing conventional coating systems. In this regard, FIG. 1 presents spectral attenuation data by measuring initial spectral attenuation on the optical fiber on a shipping spool, thereby obtaining the peaks and valleys typical of the attenuation across the full spectrum of wavelengths between the limits shown. The optical fiber is then wound onto a sandpaper-covered, fixed-diameter drum (i.e., measurement spool) as described by the IEC fixed-diameter sandpaper drum test (i.e., IEC TR62221, Method B), and another spectral attenuation curve is obtained.

The IEC fixed-diameter sandpaper drum test (i.e., IEC TR62221, Method B) provides a microbending stress situation that affects single-mode fibers even at room temperature. The sandpaper, of course, provides a rough surface that subjects the optical fiber to thousands, if not millions, of stress points. With respect to the test data presented in FIG. 1, a 300-mm diameter fiber spool was wrapped with adhesive-backed, 40-micron grade sandpaper (i.e., approximately equivalent to 300-grit sandpaper) to create a rough surface. Then, 400-meter fiber samples were wound at about 2,940 mN (i.e., a tension of 300 gf on a 300-mm diameter cylinder), and spectral attenuation was measured at 23° C.

The curves presented in FIG. 1 represent the difference between the initial spectral curve and the curve when the fiber is on the sandpaper drum, thereby providing the added loss due to microbending stresses.

Those having ordinary skill in the art will recognize cable designs are now employing smaller diameter buffer tubes and less expensive materials in an effort to reduce costs. Consequently, when deployed in such cable designs, single-mode optical fibers are less protected and thus more susceptible to stress-induced microbending. As noted, the present invention provides an improved coating system that better protects optical fibers against stresses caused by external mechanical deformations and by temperature-induced, mechanical property changes to the coatings.

As noted, conventional solutions for protecting optical fibers involved using large-diameter buffer tubes, buffer tubes made of high-modulus materials that resist deformation and stresses upon the fiber, and stronger, thicker cable jackets to resist deformations that might pinch or otherwise squeeze the optical fibers. These solutions, however, are not only costly, but also fail to address the temperature-induced stresses caused by changes to the protective coatings. In other words, conventional primary coatings possess high modulus at temperatures below their respective glass transition temperatures.

As disclosed herein, the optical fiber according to the present invention includes a primary coating possessing lower modulus and lower glass transition temperature than possessed by conventional single-mode fiber primary coatings. Even so, the improved primary coating formulation nonetheless facilitates commercial production of the present optical fiber at excellent processing speeds (e.g., 1,000 m/min or more). In this regard, the primary coating employed in the optical fibers of the present invention possesses fast curing rates—reaching 50 percent of full cure at a UV dose of about 0.3 J/cm², 80 percent of full cure at a UV dose of about 0.5 J/cm², and 90 percent of full cure at a UV dose of about 1.0 J/cm² as measured on a standard 75-micron film at 20° C. and atmospheric pressure (i.e., 760 torr) (i.e., standard temperature and pressure—STP).

FIG. 2 schematically depicts the observed relationship between the in situ modulus of a primary coating and the attenuation (added loss) of the optical fiber, here a 50-micron graded-index multimode fiber. The primary coating modulus is measured as cured on the glass fiber and the added loss is measured using a fixed-diameter sandpaper drum procedure in accordance with the IEC TR62221 microbending-sensitivity technical report and standard test procedures (e.g., IEC TR62221, Method B, Ed. 1), which are hereby incorporated by reference in their entirety.

As will be appreciated by those having ordinary skill in the art, prior, commercially available single-mode fibers typically include a Young's modulus of 100-150 psi measured in situ (i.e., on the fiber). The optical fiber according to the present invention possesses a primary coating having reduced modulus as compared with such commercially available primary coatings. Employing a lower modulus primary coating provides better cushioning around the glass fiber.

Although lower modulus of the in situ primary coating can be achieved by selectively undercuring, the present invention achieves in situ primary coating having lower modulus even approaching full cure (i.e., near full cure). In this regard, the modulus of the in situ primary coating according to the present invention is less than about 0.65 MPa (e.g., less than about 95 psi), typically less than about 0.5 MPa, and more typically less than 0.4 MPa (e.g., between about 0.3 MPa and 0.4 MPa or between about 40 psi and 60 psi). It has been determined that an in situ primary coating having a modulus of less than about 0.5 MPa significantly reduces bend sensitivity of the glass fiber. On the other hand, the modulus of the in situ primary coating according to the present invention is typically greater than about 0.2 MPa (e.g., 0.25 MPa or more).

To achieve its reduced modulus as compared with conventional optical fiber coatings, the present primary coating possesses a lower crosslink density, specifically a reduced concentration of the reactive acrylate groups. Those having ordinary skill in the art will appreciate that acrylate groups crosslink via free radical polymerization during photoinitiation (e.g., UV-induced curing during drawing operations). The reaction kinetics dictate reduced cure rates during processing. This is commercially undesirable, of course, and so the present invention implements processing modifications to provide satisfactory cure rate for the low-modulus primary coating.

There are at least two components of the curing process that retard the rate of polymerization of the primary coating. First, the combination of (i) high curing temperatures induced by exposure to a high-intensity, UV environment and (ii) the exothermic polymerization reaction slows the observed curing rate of the primary coating. Second, close proximity of stacked UV lamps, in effect, creates rapidly superposed, repeated photoinitiation periods. The reaction rate of acrylate groups under this configuration is likewise retarded—a somewhat counterintuitive result. With respect to the latter, disposing (i.e., positioning) UV lamps to increase the period between consecutive UV exposures significantly increases the degree of coating cure as compared with other conventional processes employing the same draw speed and UV dose. In this way, it is possible to process the reduced-modulus, primary coating according to the present invention in a way that achieves near-complete curing at fast fiber draw speeds, which are required for a commercially viable process. An exemplary method and apparatus for curing a coated fiber is disclosed in commonly assigned U.S. Pat. No. 7,322,122, which is hereby incorporated by reference in its entirety.

The temperature dependence of the modulus is an important consideration to ensure that the primary coating provides enhanced microbending protection in FTTx applications. A primary coating having low modulus only at room temperature would be inadequate because deployment in the field will expose the optical fiber to microbend-inducing stresses at extreme environmental temperatures (e.g., −40° C. and below). Therefore, a suitable primary coating according to the present invention possesses an exceptionally low glass transition temperature so that the primary coating remains soft and protective in extremely cold environmental conditions.

Example 1 Comparison of Mechanical Properties

FIGS. 3 and 4, respectively, depict dynamic mechanical properties of a typical commercial primary coating (i.e., the conventional primary coating) and an exemplary primary coating used in making the optical fibers according to the present invention. The conventional primary coating was a UV-curable urethane acrylate provided by DSM Desotech (Elgin, Ill.) under the trade name DeSolite® DP 1007. The exemplary primary coating according to the present invention (i.e., employed to form optical fibers of the present invention) was a UV-curable urethane acrylate provided by DSM Desotech (Elgin, Ill.) under the trade name DeSolite® DP 1011.

The data for the conventional primary coating were obtained on a Dynamic Mechanical Analyzer (DMA) at an oscillatory stress rate of 1 Hz. In doing so, the strain was maintained within the linear region of stress-strain behavior. The sample of conventional primary coating was cured on polyester to form a standard 75-micron film. A UV dose of 1 J/cm² was applied using a mercury-halide bulb operating at a 300 W/in output. This UV exposure was sufficient to ensure that the coating was on the plateau of the dose-modulus curve.

Referring to FIG. 3, the data show the equilibrium modulus to be approximately 1.5 MPa as measured on a 75-micron film. On a glass fiber (i.e., in situ), this conventional primary coating typically cures well to a modulus of about 0.8 MPa, a level indicative of many single-mode fiber primary coatings in the industry. Those having ordinary skill in the art will appreciate that modulus measurements of softer primary coatings tend to be lower on a glass fiber (i.e., in situ) as compared with on a 75-micron film.

The glass transition temperature of the conventional primary coating is estimated by the peak in tan δ to be approximately −30° C. Thus, the conventional primary coating (and similar formulations) will behave like a glassy polymer at extremely low temperatures (e.g., less than −40° C., particularly less than −50° C.). (Although stress induced by strain is time dependent at low temperatures, estimated glass transition temperature is a useful comparative property.)

A sample of the exemplary primary coating according to the present invention was likewise cured on polyester to form a comparable 75-micron film. As before, a UV dose of 1 J/cm² was applied to the primary coating using a mercury-halide bulb operating at a 300 W/in output. As noted, FIG. 4 depicts dynamic mechanical properties of the exemplary primary coating according to the present invention.

The exemplary primary coating according to the present invention exhibited an equilibrium modulus at just under 1 MPa in the cured film. The in situ modulus (i.e., measured on the glass fiber), was between about 0.3 MPa and 0.4 MPa. This is significantly lower than the respective modulus measurements for the conventional primary coating.

The glass transition temperature of the exemplary primary coating according to the present invention is estimated by the peak in tan δ at less than about −50° C. (e.g., about −60° C.). This is at least about 20° C. below the glass transition temperature of the comparative, conventional primary coating. Accordingly, primary coatings according to the present invention provide much more rapid stress relaxation during temperature excursions.

As set forth in Examples 2 and 3 (below), two different methods were used to evaluate the respective microbend sensitivities of glass fibers coated with (i) a typical commercial primary coating (i.e., the conventional primary coating) and (ii) an exemplary primary coating according to the present invention. As with Example 1 (above), the conventional primary coating was a UV-curable urethane acrylate provided by DSM Desotech (Elgin, Ill.) under the trade name DeSolite® DP 1007, and the exemplary primary coating according to the present invention (i.e., employed to form optical fibers of the present invention) was a UV-curable urethane acrylate provided by DSM Desotech (Elgin, Ill.) under the trade name DeSolite® DP 1011.

Each test method provided aggravated lateral stress conditions. Moreover, after measuring the effect on attenuation at room temperature, the test structures were temperature cycled to determine the additional loss induced by such temperature excursions.

Example 2 Comparison of Microbending Sensitivity

The first test method employed was a basket-weave, temperature cycling procedure known by those having ordinary skill in the art. According to this test procedure, optical fiber was wound at about 490 mN (i.e., a tension of 50 gf on a 300-mm diameter quartz cylinder with a 9-mm “lay”). Fifty layers were wound on the quartz drum to create numerous fiber-to-fiber crossovers. The testing procedure for Example 2 was an adaptation of IEC TR62221, Method D, which, as noted, is incorporated by reference in its entirety.

Those having ordinary skill in the art will appreciate that, at room temperature, such fiber crossovers can sometimes cause added loss (i.e., if the optical fiber is very sensitive) but that typically little or no added loss is observed. Consequently, the drum (with wound fiber) was temperature cycled twice from about room temperature through (i) −40° C., (ii) −60° C., (iii) +70° C., and (iv) +23° C. (i.e., near room temperature) while making loss measurements at 1550 nanometers. In both temperature cycles, fiber attenuation was measured after one hour at each test temperature.

FIG. 5 depicts exemplary results for single-mode glass fibers coated with, respectively, a conventional primary coating (i.e., DeSolite® DP 1007) and an exemplary primary coating according to the present invention (i.e., DeSolite® DP 1011). The respective fiber specimens were chosen to match the coating geometry, mode field diameter, and cutoff wavelength. Accordingly, the respective optical fibers employed different formulations of colored secondary coatings.

In summary, the conventional primary coating and the exemplary primary coating according to the present invention each provided good protection against microbending stresses at 23° C. Moreover, at −40° C., the optical fiber having the conventional primary coating demonstrated only a small added loss. (It would appear that at −40° C., the conventional primary coating provided adequate protection against microbending by stress relaxing in a reasonable timeframe, even though this was near its glass transition temperature.) By way of comparison, the optical fiber according to the present invention demonstrated essentially no added loss at −40° C. (i.e., better performance).

At −60° C., however, the optical fiber having the conventional primary coating demonstrated significant added loss. (This temperature extreme was well below the glass transition temperature of the conventional primary coating.) By way of comparison, the optical fiber according to the present invention demonstrated essentially no added loss at −60° C., which is close to the glass transition temperature of this embodiment of the primary coating according to the present invention.

Example 3 Comparison of Microbending Sensitivity

The second test method employed more aggressive environments (i.e., conditions) in order to evaluate the respective microbend sensitivities of (i) an optical fiber possessing a typical commercial primary coating (i.e., the conventional primary coating) and (ii) an optical fiber possessing an exemplary primary coating according to the present invention.

In particular, the second method modified the IEC fixed-diameter sandpaper drum test (i.e., IEC TR62221, Method B), which, as noted, is incorporated by reference in its entirety, to provide a microbending stress situation sufficiently harsh to affect single-mode fibers even at room temperature (i.e., a rougher drum surface than that used to measure the data depicted in FIG. 1). To do this, a 300-mm diameter quartz drum was wrapped with adhesive-backed, 220-grit sandpaper (i.e., approximately equivalent to 66-micron-grade sandpaper) to create a rough surface.

In an initial test condition, each of the respective fiber samples was wound in a single layer at about 980 mN (i.e., a tension of 100 gf on a 300-mm diameter quartz cylinder). In a modified test condition, three (3) each of the respective fiber samples was wound in a single layer at about 1,470 mN (i.e., a tension of 150 gf on a 300-mm diameter quartz cylinder). Thus, as compared with the first test condition, the second test condition increased the winding tension by 50 percent.

Using matched fiber samples (as with the basket weave/temperature cycling test of Example 2) fiber attenuation was measured after winding at room temperature (i.e., 23° C.) for each test condition. Then, the drum (with 400 meters of wound fiber) was temperature cycled from about room temperature through (i) −40° C., (ii) −60° C., and (iii) +23° C. (i.e., near room temperature) while making loss measurements at 1550 nanometers using an optical time domain reflectometer (OTDR).

The several samples of each kind of optical fiber were initially measured at 23° C. on the original spools (i.e., before winding on the roughened drum surface to establish baseline spectral attenuation) then were subjected to the foregoing rigorous testing conditions for one hour at each temperature. Fiber attenuation was measured after one hour (as in Example 2) at each test temperature.

FIG. 6, a line chart, and FIG. 7, a box plot, depict exemplary results under these more rigorous testing conditions for single-mode optical fibers that include a conventional primary coating (i.e., DeSolite® DP 1007 UV-curable urethane acrylate) and for single-mode optical fibers that include an exemplary primary coating according to the present invention (i.e., DeSolite® DP 1011 UV-curable urethane acrylate).

FIG. 6, for instance, shows that, as compared with conventional optical fibers, exemplary optical fibers according to the present invention possess reduced microbend sensitivity (i.e., a reduction of about 40-60 percent).

Likewise, FIG. 7 shows that, as compared with conventional optical fibers, exemplary optical fibers according to the present invention possess substantially reduced microbend sensitivity at a higher winding tension (i.e., 150 gf on a 300-mm diameter quartz cylinder). FIG. 7 thus illustrates that the exemplary primary coating according to the present invention (i.e., DeSolite® DP 1011 UV-curable urethane acrylate) promotes both significantly reduced and significantly more uniform microbending performance.

In accordance with the foregoing, it has been found that, as compared with a conventional coating system, the present coating system provides significant microbending improvement when used in combination with a conventional single-mode glass fiber.

It has been further found that pairing a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) and a primary coating having very low modulus (e.g., DSM Desotech's UV-curable urethane acrylate product provided under the trade name DeSolite® DP 1011) achieves optical fibers having exceptionally low losses. Additional testing was performed, therefore, to demonstrate the dramatic and unexpected reductions in microbend sensitivity provided in accordance with the present invention.

Example 4 Comparison of Microbending Sensitivity

The respective microbend sensitivities were measured for exemplary optical fibers, including (i) a conventional single-mode glass fiber with a conventional commercial coating, (ii) a bend-insensitive glass fiber with a conventional commercial coating, and (iii) a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) with the coating according to the present invention (e.g., Draka Comteq's ColorLock^(XS) brand coating system).

FIG. 8 demonstrates that the optical fiber according to the present invention, namely including a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) and a primary coating having very low modulus (e.g., DSM Desotech's UV-curable urethane acrylate product provided under the trade name DeSolite® DP 1011), provides exceptionally low attenuation losses as compared with other optical fibers. Moreover, this bend-resistant optical fiber exhibits small wavelength dependence within the transmission window between 1400 nanometers and 1700 nanometers, and is essentially unaffected by the microbend-inducing test conditions across the test spectrum.

FIG. 8 presents exemplary spectral attenuation data obtained adhering to IEC TR62221, Method B (fixed-diameter drum). In accordance with IEC TR62221, Method B, initial spectral attenuation was measured on a 440-meter sample of optical fiber wound on a shipping spool (i.e., obtaining the peaks and valleys typical of the attenuation across the full spectrum of wavelengths between the limits shown). The optical fiber was then wound at about 3 N onto a 300-mm diameter measurement spool wrapped with adhesive-backed, 40-micron grade sandpaper (i.e., approximately equivalent to 300-grit sandpaper), and another spectral attenuation curve was obtained.

Like the curves presented in FIG. 1, the curves depicted in FIG. 8 represent, at 23° C., the difference between the initial spectral curve and the curve when the fiber is on the sandpaper drum of fixed diameter, thereby providing the added loss due to microbending stresses (i.e., delta-attenuation across the spectral range).

Example 5 Comparison of Microbending Sensitivity

The respective microbend sensitivities were measured under rigorous test conditions for exemplary optical fibers, including (i) a conventional single-mode glass fiber with a conventional commercial coating and (ii) a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) with the coating according to the present invention (e.g., Draka Comteq's ColorLock^(XS) brand coating system).

FIG. 9 demonstrates that, even under extremely harsh conditions, the optical fiber according to the present invention, namely including a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) and a primary coating having very low modulus (e.g., DSM Desotech's UV-curable urethane acrylate product provided under the trade name DeSolite® DP 1011), provides surprisingly low attenuation losses as compared with other optical fibers.

The testing procedure for Example 5 was an adaptation of IEC TR62221, Method B, which, as noted, is incorporated by reference in its entirety. For this modified IEC fixed-diameter sandpaper drum test, a 300-mm diameter quartz drum was wrapped with adhesive-backed, 180-grit sandpaper (i.e., approximately equivalent to 78-micron-grade sandpaper) to create an even rougher surface than that described in Example 3 (above). Then, 440-meter fiber samples were wound in a single layer at about 1,470 mN (i.e., a controlled back tension of 150 gf on the 300-mm diameter quartz cylinder using a Delachaux optical fiber winding apparatus), and spectral attenuation was measured.

FIG. 9 presents exemplary temperature-cycle data for three specimens of standard single-mode fiber (i.e., a conventional single-mode glass fiber with a conventional commercial coating) and three specimens of optical fiber according to the present invention (i.e., a bend-insensitive glass fiber with improved coating according to the present invention). As noted, 440 meters of optical fiber is wound onto the aforementioned sandpaper-covered, fixed-diameter drum. One hour after winding, fiber attenuation was measured at room temperature (i.e., 23° C.) using an optical time domain reflectometer (OTDR). Then, the drum (with 440 meters of wound fiber) was temperature cycled from about room temperature through (i) −40° C. and (ii) −60° C. in a temperature-controlled chamber. Fiber attenuation at 1550 nanometers was measured by an OTDR after one hour of equilibration at both −40° C. and −60° C.

Microbending sensitivity (S_(m)) may be described as αR/T, wherein a is the attenuation increase on the drum (dB/km), R is the radius of the fixed drum (mm), and T is the winding tension applied to the fiber (N). See e.g., IEC TR62221 Technical Report (Microbending Sensitivity). In addition to the parameters α, R, and T, however, the microbending-sensitivity metric obtained from the fixed-diameter sandpaper drum test is dependent on the coarseness of the sandpaper employed on the measurement drum.

Table 1 (below) presents the microbending-sensitivity metric obtained from the attenuation data (at a wavelength of 1550 nanometers) depicted in FIG. 9 (i.e., employing 180-grit sandpaper). Table 1 shows that, as compared with a conventional standard single-mode fiber, the optical fiber according to the present invention provides microbending sensitivity that is about 2×-10× lower at 23° C. and about 2×-5× lower at −40° C.:

TABLE 1 (Microbend Sensitivity) 23° C. −40° C. −60° C. Optical Fiber (dB/km)/ (dB/km)/ (dB/km)/ (Coating Color) (N/mm) (N/mm) (N/mm) Conventional SMF 139.9 220.6 331.8 (blue) Conventional SMF 261.0 329.7 417.9 (red) Conventional SMF 104.3 161.9 228.0 (aqua) BendBright^(XS) ® w/ 35.8 76.5 163.4 ColorLock^(XS) (slate) BendBright^(XS) ® w/ 30.1 70.6 144.2 ColorLock^(XS) (red) BendBright^(XS) ® w/ 42.7 84.7 166.4 ColorLock^(XS) (aqua)

Example 6 Comparison of Microbending Sensitivity

The respective microbend sensitivities were further measured for exemplary optical fibers, including (i) a conventional single-mode glass fiber with a conventional commercial coating and (ii) a bend-insensitive glass fiber (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) with the coating according to the present invention (e.g., Draka Comteq's ColorLock^(XS) brand coating system).

The testing procedure for Example 6 was an adaptation of IEC TR62221, Method B, which, as noted, is incorporated by reference in its entirety. For this modified IEC fixed-diameter sandpaper drum test, a 300-mm diameter quartz drum was wrapped with adhesive-backed, 220-grit sandpaper (i.e., approximately equivalent to 66-micron-grade sandpaper) to create a rough surface like that described in Example 3. Each of the fiber samples was wound in a single layer at about 1,470 mN (i.e., a tension of 150 gf on a 300-mm diameter quartz cylinder). As compared with the test conditions of Example 5, the test conditions of Example 6 employed finer grade sandpaper (i.e., 220-grit rather than 180-grit).

As in Example 3, using matched fiber samples, fiber attenuation was measured after winding at room temperature (i.e., 23° C.). Then, the drum (with about 400 meters of wound fiber) was temperature cycled from about room temperature through (i) −40° C., (ii) −60° C., and (iii) +23° C. (i.e., near room temperature) while making loss measurements at 1550 nanometers using an optical time domain reflectometer (OTDR).

Three (3) samples of each kind of optical fiber were initially measured at 23° C. on the original spools (i.e., before winding on the roughened drum surface to establish baseline spectral attenuation) and then were subjected to the foregoing rigorous testing conditions for one hour at each temperature. Fiber attenuation was measured after one hour at each temperature.

FIG. 10 depicts exemplary results for single-mode optical fibers that include a conventional primary coating (i.e., DeSolite® DP 1007 UV-curable urethane acrylate) and for bend-insensitive glass fibers (e.g., Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)®) that include a primary coating having very low modulus (i.e., DSM Desotech's UV-curable urethane acrylate product provided under the trade name DeSolite® DP 1011).

FIG. 10 demonstrates that the optical fiber according to the present invention, namely Draka Comteq's single-mode glass fibers available under the trade name BendBright^(XS)® with a primary coating having very low modulus (e.g., DSM Desotech's UV-curable urethane acrylate product provided under the trade name DeSolite® DP 1011), provides exceptionally low attenuation losses as compared with standard single-mode optical fibers (SSMF).

In addition, FIGS. 11 and 12 depict attenuation and microbend sensitivity, respectively, at a wavelength of 1550 nanometers as a function of MAC number (i.e., mode field diameter divided by cutoff wavelength) for various exemplary optical fibers in accordance with the standard IEC fixed-diameter sandpaper drum test (i.e., IEC TR62221, Method B). The respective attenuation data depicted in FIG. 11 (added loss) and FIG. 12 (microbend sensitivity) were obtained at 23° C. under the test conditions previously described with respect to FIG. 1 (i.e., 400-meter fiber samples were wound at about 2,940 mN—a tension of 300 gf—on a 300-mm diameter fiber spool wrapped with adhesive-backed, 40-micron grade sandpaper).

FIG. 11 shows that Draka Comteq's bend-resistant, single-mode glass fiber available under the trade name BendBright^(XS)® in combination with Draka Comteq's ColorLock^(XS) brand coating system provides outstanding performance with respect to added loss.

FIG. 12 shows that Draka Comteq's bend-resistant, single-mode glass fiber available under the trade name BendBright^(XS)® in combination with Draka Comteq's ColorLock^(XS) brand coating system provides superior microbend sensitivity (i.e., microbend sensitivity of 0.01 to 0.03 (dB/km)/(gf/mm)).

The optical fibers according to the present invention typically further include a tough secondary coating to protect the primary coating and glass fiber from damage during handling and installation. For example, the secondary coating might have a modulus of between about 800 and 1,000 MPa (e.g., about 900 MPa) as measured on a standard 75-micron film. As disclosed herein, this secondary coating may be inked as a color code or, preferably, may be color-inclusive to provide identification without the need for a separate inking process.

In one embodiment according to the present invention, the secondary coating, which surrounds the primary coating to thereby protect the fiber structure, features an inclusive coloring system (i.e., not requiring an extra layer of ink to be added for color coding). The colors, which conform to Munsell standards for optical fiber color-coding, are enhanced for brightness and visibility under dim lighting (e.g., in deep shade or in confined spaces, such as manholes) and are easily distinguished against both light and dark backgrounds.

Furthermore, the secondary coating features a surface that provides an excellent interface with ribbon matrix material so that the matrix separates easily from the colored fiber in a way that does not sacrifice robustness. The mechanical properties of the colored secondary coating are balanced with those of the primary coating so that, in heat stripping, the coating/matrix composite separates cleanly from the glass fibers.

Employing Draka Comteq's bend-resistant, single-mode glass fiber available under the trade name BendBright^(XS)® (or the trade name BendBright-Elite™) with the present dual-coating system, which includes a low-modulus primary coating, has been found to reduce microbending sensitivity by between about one to two orders of magnitude relative to standard single-mode fiber (SSMF) at the key transmission frequencies of 1550 nanometers and 1625 nanometers. As noted, such optical fiber not only provides outstanding resistance to microbending and macrobending, but also complies with the ITU-T G.657.A/B and ITU-T G.652.D requirements.

In particular, Draka Comteq's bend-resistant, single-mode glass fiber available under the trade name BendBright^(XS)® (e.g., enhanced with Draka Comteq's ColorLock^(XS) brand coating system) provides resistance to macrobending required for sustained bends having a radius as low as five (5) millimeters with an estimated failure probability of less than two (2) breaks per million full circle bends (i.e., 360°) over 30 years in a properly protected environment. These bend-resistant optical fibers facilitate the rapid deployment of small, flexible cables for the delivery of fiber to the premises/business/home (i.e., FTTx) by virtue of the optical fiber's ability to sustain a loss-free transmission through small-radius bends. Cables employing such bend-resistant optical fibers may be routed around sharp bends, stapled to building frame, coiled, and otherwise employed in demanding environments while retaining clear and strong signal transmission.

The bend-insensitive optical fibers according to the present invention facilitate the reduction in overall optical-fiber diameter. As will be appreciated by those having ordinary skill in the art, a reduced-diameter optical fiber is cost-effective, requiring less raw material. Moreover, a reduced-diameter optical fiber requires less deployment space (e.g., within a buffer tube and/or fiber optic cable), thereby facilitating increased fiber count and/or reduced cable size. In this regard, U.S. Patent Application Ser. No. 61/248,319 and U.S. patent application Ser. No. 12/614,011 for a Reduced-Diameter Optical Fiber (Overton) are hereby incorporated by reference in their entirety.

Those having ordinary skill in the art will recognize that an optical fiber with a primary coating (and an optional secondary coating and/or ink layer) typically has an outer diameter of between about 235 microns and about 265 microns (μm). The component glass fiber itself (i.e., the glass core and surrounding cladding layers) typically has a diameter of about 125 microns, such that the total coating thickness is typically between about 55 microns and 70 microns.

With respect to the optical fiber according to the present invention, the component glass fiber typically has an outer diameter of about 125 microns. With respect to the optical fiber's surrounding coating layers, the primary coating typically has an outer diameter of between about 175 microns and about 195 microns (i.e., a primary coating thickness of between about 25 microns and 35 microns) and the secondary coating typically has an outer diameter of between about 235 microns and about 265 microns (i.e., a secondary coating thickness of between about 20 microns and 45 microns). Optionally, the optical fiber according to the present invention may include an outermost ink layer, which is typically between two and ten microns in thickness.

In an alternative embodiment, an optical fiber according to the present invention may possess a reduced diameter (e.g., an outermost diameter between about 150 microns and 230 microns). In this alternative optical fiber configuration, the thickness of the primary coating and/or secondary coating is reduced, while the diameter of the component glass fiber is maintained at about 125 microns. (Those having ordinary skill in the art will appreciate that, unless otherwise specified, diameter measurements refer to outer diameters.) By way of example, in such embodiments the primary coating layer may have an outer diameter of between about 135 microns and about 175 microns (e.g., about 160 microns), and the secondary coating layer may have an outer diameter of between about 150 microns and about 230 microns (e.g., more than about 165 microns, such as 190-210 microns or so). In other words, the total diameter of the optical fiber is reduced to less than about 230 microns (e.g., about 200 microns).

As discussed previously, combining (i) a coating system according to the present invention with (ii) a glass fiber having a refractive index profile that itself provides bend resistance (e.g., low macrobending sensitivity) has been found to provide unexpectedly superior reductions in microbend sensitivity. Indeed, bend-insensitive glass fibers are especially suitable for use with the coating system of the present invention (e.g., Draka Comteq's ColorLock^(XS) brand coating system). The respective refractive-index profiles of exemplary bend-insensitive glass fibers (i.e., exemplary bend-insensitive glass designs) are further discussed hereinafter.

As will be understood by those having ordinary skill in the art, a refractive index profile of an optical fiber is a graphical representation of the value of the refractive index as a function of optical fiber radius. Conventionally, the distance r to the center of the fiber is shown along the abscissa, and the difference between the refractive index and the refractive index of the fiber cladding is shown along the ordinate axis. The optical fiber refractive index profile is referred to as a “step” profile, a “trapezoidal” profile, a “parabolic” profile, or a “triangular” profile for graphs having the respective shapes of a step, a trapezoid, a parabola, or a triangle. These curves are generally representative of the theoretical or reference index profile (i.e., set profile) of the fiber. The fiber manufacturing constraints and stresses may lead to a slightly different profile.

An optical fiber conventionally includes an optical core, whose function is to transmit and possibly to amplify an optical signal, and an optical cladding, whose function is to confine the optical signal within the core. For this purpose, the refractive indexes of the core n_(c) and the outer cladding n_(g) are such that n_(c)>n_(g). As is well known, the propagation of an optical signal in a single-mode optical fiber is divided into a fundamental mode (i.e., dominant mode, known as LP01) guided in the core and into secondary modes (i.e., cladding modes) guided over a certain distance in the core-cladding assembly.

Conventionally, step-index fibers are used as line fibers for optical fiber transmission systems. These optical fibers exhibit a chromatic dispersion and a chromatic dispersion slope corresponding to specific telecommunication recommendations. As noted, for compatibility between the optical systems of different manufacturers, the International Telecommunication Union (ITU) has established a recommendation with a norm referenced ITU-T G.652, which must be met by a Standard Single Mode Fiber (SSMF).

This G.652 standard for transmission fibers, recommends inter alia, a nominal range of 8.6 microns to 9.5 microns for the Mode Field Diameter (MFD) at a wavelength of 1310 nanometers, which can vary with +/−0.4 microns due to manufacturing tolerances; a maximum of 1260 nanometers for the cabled cut-off wavelength; a range of 1300 nanometers to 1324 nanometers for the dispersion cancellation wavelength (denoted 4); and a maximum chromatic dispersion slope of 0.092 ps/(nm²·km) (i.e., ps/nm²/km).

The cabled cut-off wavelength is conventionally measured as the wavelength at which the optical signal is no longer single mode after propagation over 22 meters of fiber, such as defined by subcommittee 86A of the International Electrotechnical Commission under standard IEC 60793-1-44.

In most cases, the secondary mode most resistant to bending losses is the LP11 mode. The cable cut-off wavelength is, therefore, the wavelength beyond which the LP11 mode is sufficiently weakened after propagation over 22 meters of fiber. The method proposed by the standard involves considering that the optical signal is single mode when the attenuation of the LP11 mode is greater than or equal to 19.3 dB.

In addition, as previously noted, it is desirable to reduce bending sensitivity of optical fibers for use as termination fibers. Typical solutions to reduce bending losses are to influence the MAC value. For a given fiber, the so-called MAC value is defined as the ratio of the mode field diameter of the fiber at 1550 nanometers to the effective cut-off wavelength λ_(ceff). The effective cut-off wavelength is conventionally measured as the wavelength at which the optical signal is no longer single mode after propagation over two meters of fiber such as defined by sub-committee 86A of the International Electrotechnical Commission under standard IEC 60793-1-44. The MAC value is used to assess fiber performance, particularly to achieve a compromise between mode field diameter, effective cut-off wavelength, and bending losses.

In this regard, FIG. 13 depicts the experimental results that illustrate bending losses at a wavelength of 1625 nanometers with a bend radius of 15 millimeters in a SSMF fiber in relation to the MAC value at a wavelength of 1550 nanometers. FIG. 13 shows that the MAC value influences fiber bending and that these bending losses may be reduced by lowering the MAC value.

An exemplary bend-insensitive glass fiber for use in the present invention is disclosed in U.S. Patent Application Publication No. US 2007/0127878 A1 and its related U.S. patent application Ser. No. 11/556,895 for a Single Mode Optical Fiber (de Montmorillon et al.), now U.S. Pat. No. 7,623,747. As noted, each of these commonly assigned patent documents is incorporated by reference in its entirety. Combining (i) a bend-insensitive glass fiber having the refractive index profile as disclosed in U.S. Patent Application Publication No. US 2007/0127878 A1 and a coating according to the present invention can achieve optical fibers having exceptional reductions in microbend sensitivity.

The bend-insensitive glass fiber disclosed in U.S. Patent Application Publication No. US 2007/0127878 A1 (i.e., the “disclosed fiber”) includes a central core, a first inner cladding, a deeply buried second inner cladding, which contains germanium, and an outer cladding. Even though germanium is used as a dopant to increase the index of silica, the presence of germanium in the deeply buried cladding makes it possible to increase the elastic-optical coefficient of the buried cladding. Therefore when stresses are applied to the fiber, in particular when the fiber undergoes bending or micro-bending, the presence of the deeply buried cladding containing germanium limits the effects of stresses on the changes in refractive index in the fiber. The optical losses are therefore reduced when such stresses are applied to a fiber having a second deeply buried inner cladding containing germanium.

More particularly, the optical transmission fiber possesses (i) a central core having an index difference Δn₁ with an outer optical cladding; (ii) a first inner cladding having an index difference Δn₂ with the outer cladding; (iii) a second, buried inner cladding having an index difference Δn₃ with the outer cladding of less than −3.10⁻³, and (iv) containing germanium in a weight concentration of between 0.5 percent and 7 percent.

According to one embodiment of the fiber, the index difference Δn₃ of the second inner cladding with the outer cladding is greater than −15.10⁻³. The index difference between the central core and the first inner cladding (Δn₁−Δn₂) may lie between 3.9×10⁻³ and 5.9×10⁻³. According to another embodiment, the second buried cladding has a radius of between 12 microns and 25 microns.

The central core may have a radius of between 3.5 microns and 4.5 microns, and show an index difference with the outer cladding of between 4.2×10⁻³ and 6.1×10⁻³.

In yet another embodiment, the first inner cladding has a radius of between 7.5 microns and 14.5 microns and shows an index difference with the outer cladding between −1.2×10⁻³ and 1.2×10⁻³.

The fiber disclosed herein may be described in terms of the integral I₁ of the central core, which is defined as:

I₁ = ∫₀^(r₁)Dn(r)⋅ 𝕕r ≈ r₁ × Dn₁ and, in preferred embodiments, lies between 17×10⁻³ microns and 24×10⁻³ microns.

In terms of yet another characteristic, at a wavelength of 1310 nanometers, the present fiber shows a chromatic dispersion slope of 0.093 ps/nm²/km or less. The present fiber may also show (i) cancellation of chromatic dispersion at a wavelength of between 1300 nanometers and 1324 nanometers and/or (ii) a cable cut-off wavelength of 1260 nanometers or less.

The disclosed optical fiber may be further described in terms of its bending losses under various operating conditions. At a wavelength of 1625 nanometers, the bending losses for a winding of 100 turns around a bending radius of 15 millimeters are 1 dB or less. At a wavelength of 1625 nanometers, the present fiber shows bending losses for a winding of 1 turn around a bend radius of 11 millimeters, of 0.5 dB or less. Along these lines, again at a wavelength of 1625 nanometers, the present fiber shows bending losses for a winding of 1 turn around a bend radius of 5 millimeters, of 2 dB or less. Finally, to address yet another characteristic of this optical fiber, up to a wavelength of 1625 nanometers, the disclosed optical fiber shows microbending losses, measured by the so-called fixed diameter drum method, of 0.8 dB/km or less.

More particularly, the bend-insensitive glass fiber disclosed in U.S. Patent Application Publication No. US 2007/0127878 A1 has a central core, a first inner cladding, and a second, buried, inner cladding. By buried cladding is meant a radial portion of a fiber with a refractive index that is lower than the index of the outer cladding. The second, buried, inner cladding has an index difference with the outer cladding that is less than −3×10⁻³ and may reach −15×10⁻³. Also, the buried cladding contains germanium in a weight concentration of between 0.5 percent and 7 percent.

As known per se, an optical fiber is obtained by the drawing of a preform. For example, the preform may be a glass tube (pure silica) of very high quality which forms part of the outer cladding and surrounds the central core and the inner claddings of the fiber; this tube can then be sleeved or refilled to increase its diameter before proceeding with the drawing operation on a draw tower. To manufacture the preform, the tube is generally mounted horizontally and held in place at its two ends by glass rods in a lathe; the tube is then rotated and locally heated to deposit components determining the composition of the preform. This composition determines the optical characteristics of the future fiber.

The depositing of components in the tube is commonly called “doping,” i.e., “impurities” are added to the silica to modify its refractive index. Hence, germanium (Ge) or Phosphorus (P) increase the refractive index of the silica; they are often used to dope the central core of the fiber. Also, fluorine (F) or Boron (B) lower the refractive index of the silica; they are often used to form buried claddings or as co-dopants with germanium when it is desired to compensate for the increase in refractive index in a photosensitive cladding.

A preform with a buried cladding is difficult to manufacture. Fluorine does not incorporate easily into silica when heated beyond a certain temperature, whereas a high temperature is required to manufacture glass. The compromise between the high temperature required for glass-making and the low temperature that promotes proper incorporation of the fluorine makes it practically impossible to obtain indexes much lower than that of silica.

It is proposed herein to manufacture the preform of the present fiber using a PCVD technique (Plasma Chemical Vapor Deposition) since it allows reactions at lower temperatures than conventional techniques (CVD, VAD, OVD) by ionizing the reaction components. This manufacturing technique is described in U.S. Pat. Nos. RE 30,635 and 4,314,833; the technique allows major incorporation of fluorine in the silica in order to form deeply buried claddings.

The use of the PCVD technique to manufacture the fiber disclosed herein also makes it possible to add germanium to the buried cladding. As indicated previously, germanium increases the refractive index of the silica; it is therefore generally highly unadvisable to incorporate the same in a fiber section for which it is sought to obtain a lower refractive index than silica. PCVD makes it possible however to produce a high number of highly reactive fluorine ions; it then becomes possible to add germanium to the reaction and nonetheless to obtain a buried inner cladding.

Therefore, the present fiber comprises germanium within the assembly of inner claddings including the cladding with an index of refraction less than −3×10⁻³. The presence of germanium in the buried cladding modifies the viscosity of the silica and the elastic-optical coefficient in this cladding layer.

FIG. 14 illustrates an index profile for this transmission fiber. The illustrated profile is a set profile, i.e., it represents the theoretical profile of the fiber. The fiber actually obtained after drawing from a preform possibly has a substantially different profile.

The single-mode transmission fiber includes (i) a central core having an index difference Δn₁ with an outer cladding that serves as an optical cladding; (ii) a first inner cladding having an index difference Δn₂ with the outer cladding; and (iii) a second inner cladding which is deeply buried and has an index difference Δn₃ with the outer cladding. The refractive indexes in the central core, the first cladding, and the second inner cladding are substantially constant over their entire width; the set profile is therefore truly a single-mode fiber. The width of the core is defined by its radius r₁ and the width of the claddings by their respective outer radii r₂ and r₃.

To define a set index profile for an optical fiber, the index of the outer cladding is generally taken as reference. The index values of the central core, buried claddings and the ring (i.e., the first inner cladding) are then given as index differences Δn_(1,2,3). Generally, the outer cladding is formed of silica, but this outer cladding may be doped to increase or reduce its refractive index, for example, to modify the signal propagation characteristics.

Each section of the fiber profile can therefore be defined using integrals which associate the variations in indexes with the radius of each fiber section.

Three integrals can be defined for the present fiber. The integral values represent the core surface I₁, the surface of the first inner cladding I₂ and the surface of the second, buried, inner cladding I₃. The expression “surface” is not to be construed geometrically but corresponds to a value taking two dimensions into account. These three integrals can be expressed as follows:

I₁ = ∫₀^(r₁)Dn(r)⋅ 𝕕r ≈ r₁ × Dn₁ I₂ = ∫_(r₁)^(r₂)Dn(r)⋅ 𝕕r ≈ (r₂ − r₁) × Dn₂ I₃ = ∫_(r₂)^(r₃)Dn(r)⋅ 𝕕r ≈ (r₃ − r₂) × Dn₃

Table 2 below gives the limit values of radii and index differences, and the limit values of the integral I₁ that are required so that the fiber shows reduced bending losses and microbending losses while meeting the optical propagation criteria of G.652 standard for transmission fibers. The values given in the table correspond to the set profiles of the fibers.

TABLE 2 r₃ Δn₁ Δn₂ Δn₃ I₁ r₁ (μm) r₂ (μm) (μm) r₁/r₂ (×10³) (×10³) (×10³) Δn1-Δn₂ (μm × 10³) 3.5 7.5 12.0 0.27 4.2 −1.2 −15 3.9 17 4.5 14.5 25.0 0.5 6.2 1.2 −3 5.9 24

The value of the integral I₁ of the central core influences the shape and size of the fundamental propagation mode of the signal in the fiber. An integral value for the central core of between 17×10⁻³ microns and 24×10⁻³ microns makes it possible, in particular, to maintain a mode field diameter that is compatible with the G.652 standard.

Table 3 below gives examples of possible index profiles for the disclosed transmission fiber. The first column allocates a reference to each profile. The following columns give the radii values of each section (r₁ to r₃); and the following columns give the values of the index differences of each section with the outer cladding (Δn₁ to Δn₃). The index values are measured at the wavelength of 633 nanometers.

TABLE 3 Δn₁ Δn₂ Δn₃ Example r₁ (μm) r₂ (μm) r₃ (μm) (×10³) (×10³) (×10³) 1 2.86 6.90 13.24 5.41 2.00 −3.70 2 3.86 9.50 15 5.16 0.69 −5.0 3 4.02 9.55 15 5.31 0.45 −5.0 4 3.86 8.66 15 5.41 0.85 −5.0

The present transmission fiber, having an index profile such as described previously, shows reduced bending losses and microbending losses at useful wavelengths. In addition, the present fiber meets the criteria of G.652 standard. Tables III and IV below illustrate the simulated optical characteristics for transmission fibers corresponding to the index profiles in Table 3.

In Table 4, column one reproduces the references of Table 3. The following columns, for each fiber profile, give the values of the effective cut-off wavelength λ_(ceff), cable cut-off wavelength λ_(CC), mode field diameters 2W02 for the wavelengths 1310 nanometers and 1550 nanometers, the cancellation wavelength of the chromatic dispersion λ_(o), the dispersion slope P₀ at λ₀, and the chromatic dispersions C for the wavelengths 1550 nanometers and 1625 nanometers.

In Table 5, column one reproduces the references of Table 4. The following column gives the MAC values at a wavelength of 1550 nanometers. The three following columns give the values for the bending losses BL for the respective bending radii of 5, 11, and 15 millimeters at a wavelength of 1625 nanometers. The following column, for a radius of 15 millimeters, gives the relative bending losses normalized with respect to the standard bending losses of a SSMF fiber having the same MAC value at a wavelength of 1550 nanometers. The second to last column gives the microbending losses obtained with the pin-array test (10 pins of 1.5 millimeters) at a wavelength of 1550 nanometers.

The pin-array test uses an array of ten polished needles, of diameter 1.5 millimeters and spaced apart by 1 cm. The fiber is woven across the array orthogonally to the axis of the needles. The fiber and the array are pressed between two rigid plates coated with a layer of approximately 3 millimeters of high density polyethylene foam. The layers of the assembly (plates, array, fiber) are positioned horizontally and the assembly is covered with a 250-gram weight. The last column indicates the microbending losses measured using the fixed diameter drum method at a wavelength of 1625 nanometers. This method is described in the technical recommendations of the International Electrotechnical Commission, sub-committee 86A under reference IEC TR-62221. The diameter of the drum used is 60 cm; the drum is covered with extra-fine sandpaper. The values of the bending losses (BL) are indicated at a wavelength of 1625 nanometers.

TABLE 4 2W02 2W02 C C λ_(ceff) λ_(CC) @1310 nm @1550 nm λ₀ P₀ @ 1550 nm @ 1625 nm N (μm) (μm) (μm²) (μm²) (nm) (ps/nm²/km) (ps/nm/km) (ps/nm/km) 1 1.13 <1.26 9.10 10.18 1308 0.097 19.2 23.9 2 1.23 <1.26 9.16 10.36 1312 0.091 18.1 22.9 3 1.25 <1.26 9.01 10.13 1318 0.089 17.3 22.0 4 1.25 <1.26 9.00 10.08 1318 0.091 17.8 22.5

TABLE 5 BLμ BLμ BL BL BL Pin-array Drum R = 5 mm R = 11 mm R = 15 mm BLrel test method MAC @1625 nm @1625 nm @1625 nm R = 15 mm @1550 nm @1625 nm N^(o) @1550 nm (dB/turn) (dB/turn) (dB/100 turns) @1625 nm (dB) (dB/km) 1 9.0 ≦5 ≦2 1/5 2 8.4 2 ≦0.5 ≦1 1/5 0.025 ≦0.8 3 8.1 1 ≦0.1 ≦0.4 1/5 ≦0.025 ≦0.8 4 8.1 1 ≦0.1 ≦0.4 1/5 ≦0.025 ≦0.8

It can be seen in Table 4 that examples 2-4 indeed comply with the G.652 standard; example 1 shows a dispersion slope P₀ lying slightly outside the G.652 standard.

In particular, the fiber in examples 2 to 4 shows cancellation of chromatic dispersion for a wavelength of between 1300 nanometers and 1324 nanometers; this is in agreement with the G.652 standard. The fiber in examples 2 to 4 also shows, for a wavelength of 1310 nanometers, a chromatic dispersion slope that is 0.093 ps/nm² km or less, which complies with the G.652 standard. Also the fiber in examples 2 to 4 shows a cable cut-off wavelength that is 1260 nanometers or less, meeting the criteria of the G.652 standard which requires a cabled cut-off wavelength of 1260 nanometers or less.

In addition, it can be seen in Table 5 that examples 2 to 4 exhibit distinctly improved bending losses with respect to the losses of standard SSMF transmission fiber. The microbending losses are also improved.

The graphs in FIGS. 15 a, 15 b, and 15 c show bending loss measurements obtained with the disclosed optical fibers as well as bending loss measurements for standard fibers. The measurements correspond to bending radii of R=5 mm, R=11 mm and R=15 mm at a wavelength of 1625 nanometers. The bending losses here are given at the end of one loop (for R=5 mm and R=11 mm) or at the end of 100 loops (for R=15 mm).

FIG. 16 a shows microbending losses for the disclosed optical fibers and characterized by the pin-array test as measured at a wavelength of 1550 nanometers. The microbending loss values are shown in relation to the MAC value at a wavelength of 1550 nanometers for different SSMF fibers and for the glass fiber disclosed in U.S. Patent Application Publication No. US 2007/0127878 A1.

FIG. 16 b shows microbending losses using the fixed diameter drum test in relation to the wavelength for a SSMF fiber and for the disclosed fiber having MAC values at a wavelength of 1550 nanometers of 8.11 and 8.31, respectively.

Also, the graphs in FIGS. 16 a and 16 b clearly show that the sensitivity of the present fiber to microbending is markedly reduced with respect to that of a SSMF fiber. It can be seen in FIG. 16 a that the microbending losses (pin-array test) measured for the fiber disclosed in U.S. Patent Application Publication No. US 2007/0127878 A1, having a MAC value of 8.44 at a wavelength of 1550 nanometers, amounts to 0.025 dB, whereas the microbending losses are ten times higher for a SSMF fiber having the same MAC value. It can also be seen in FIG. 16 b that microbending losses (fixed drum method) for the disclosed fiber increase much more slowly with the wavelength than for a SSMF fiber which has a greater MAC value however at the 1550 nanometers wavelength. In this graph, it can be seen that the present fiber guarantees a sensitivity to microbending up to long wavelengths, greater than 1650 nanometers, which is equivalent to the sensitivity that can be guaranteed for a SSMF fiber up to a wavelength of 1550 nanometers.

The present transmission fiber may be manufactured by drawing a preform having one of the above-described index profiles. The preform profiles may be made, for example, from a sleeve of silica in which layers of doped silica are deposited. Deposition may be made by a Plasma Chemical Vapor Deposition (PCVD) type deposition method mentioned previously. This chemical deposition in the vapor form activated by plasma (PCVD) is particularly suitable for obtaining a buried inner cladding layer for the present fiber. In preferred embodiments, this buried cladding layer includes germanium in a weight concentration between 0.5 percent and 7 percent. The weight concentration of germanium is preferably between 0.5 percent and 1.5 percent since this allows an optimum balance between lower costs and more ease of manufacturing on the one hand and good fiber characteristics on the other hand.

Another exemplary bend-insensitive glass fiber for use in the present invention is disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1 and its related U.S. patent application Ser. No. 11/697,994 for a Single-Mode Optical Fiber (de Montmorillon et al.), now U.S. Pat. No. 7,587,111. As noted, each of these commonly assigned patent documents is incorporated by reference in its entirety. Combining (i) a bend-insensitive glass fiber having the refractive index profile as disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1 and a coating according to the present invention can achieve optical fibers having exceptional reductions in microbend sensitivity.

The bend-insensitive glass fiber disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1 (i.e., the “disclosed fiber”) embraces a particular step-index profile with a first highly depressed section and a weakly depressed second section. With such a structure, it is possible to effectively reduce the bending losses at constant MAC while strongly minimizing the leakage modes of a higher order. Thus, unlike the fibers from the prior art having a step-index structure with a depressed section, this disclosed fiber has a cable cut-off wavelength which remains less than 1260 nanometers. This disclosed fiber thus complies with the G.652 standard.

More particularly and as schematically depicted in FIG. 17, the disclosed optical transmission fiber 10 includes: a central core 11 having an index difference (Dn₁) with an outer optical cladding 16; a first intermediate inner cladding 12 having an index difference (Dn₂) with the outer optical cladding 16; a first depressed inner cladding 13 having an index difference (Dn₃) with the outer optical cladding 16 that is less than or equal to −5×10⁻³; a second intermediate inner cladding 14 having an index difference (Dn₄) with the outer optical cladding 16; a second depressed inner cladding 15 having an index difference (Dn₅) with the outer optical cladding 16 that is inferior, in absolute value, to the index difference Dn₃ between the first depressed inner cladding 13 and the outer optical cladding 16; and wherein, for a wavelength of 1625 nanometers, the optical fiber 10 has bending losses less than or equal to 0.1 dB/10 turns for a bending radius of 15 millimeters and bending losses less than or equal to 0.5 dB/turn for a bending radius of 7.5 millimeters.

The glass fiber disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1 may include one or more of the following characteristics: the index difference between the second depressed inner cladding and the outer optical cladding is between −0.3×10⁻³ and −3×10⁻³; the index difference between the central core and the first intermediate inner cladding is between 4.5×10⁻³ and 6.0×10⁻³; the central core has a radius between 3.5 microns and 4.5 microns for an index difference with the outer optical cladding between 5.0×10⁻³ and 5.6×10⁻³; the first intermediate inner cladding has a radius between 9 microns and 12 μm; the first depressed inner cladding has a radius between 14 microns and 16 μm; the second intermediate inner cladding has a substantially zero index difference with the outer optical cladding; the second intermediate inner cladding has a radius between 18 microns and 20 μm; the second depressed inner cladding has a radius between 25 microns and 40 μm; bending losses less than or equal to 0.1 dB/100 turns for a bending radius of 20 millimeters, at the wavelength of 1625 nanometers; bending losses less than or equal to 1 dB/turn for a bending radius of 5 millimeters, at the wavelength of 1625 nanometers; microbending losses, according to the so-called method of the fixed diameter drum (“touret à diamètre fixe”), less than or equal to 0.8 dB/km up to a wavelength of 1625 nanometers; a cable cut-off wavelength less than or equal to 1260 nanometers; a mode field diameter between 8.6 microns and 9.5 microns for a wavelength of 1310 nanometers; a ratio (MAC) of the mode field diameter of the fiber at 1550 nanometers over the effective cut-off wavelength (λ_(ceff)) less than 8.2; a zero chromatic dispersion wavelength (λ₀) between 1300 nanometers and 1324 nanometers with a chromatic dispersion slope inferior or equal to 0.092 ps/nm²/km at this wavelength.

Regarding the bend-insensitive glass fiber disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1 and with reference to FIG. 17, the optical fiber 10 has a central core 11, a first intermediate inner cladding 12, and a first depressed inner cladding 13. The fiber also has a second intermediate inner cladding 14 and a second depressed inner cladding 15. By depressed inner cladding, it is meant that a radial portion of the fiber 10 has a refractive index less than the index of the outer optical cladding 16. The first depressed inner cladding 13 has an index difference with the outer optical cladding 16 that is typically less than −5×10⁻³ but that may reach −15×10⁻³. The second depressed inner cladding 15 has a smaller index difference with the outer cladding 16 than with the first depressed inner cladding 13; this index difference is typically between −0.3×10⁻³ and −3×10⁻³.

As will be appreciated by those having ordinary skill in the art, FIG. 17 is a schematic representation of an exemplary fiber. FIG. 17 is intended to depict the relative positions of the central core 11 and the respective cladding layers 11-16 within the fiber 10. Accordingly, the central core 11 and cladding layers 11-16 are not necessarily drawn to scale (e.g., the outer cladding 16).

FIG. 18 illustrates an index profile for a transmission fiber disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1. The illustrated profile is a set profile (i.e., representative of the theoretical profile of the fiber). Fiber actually obtained after fiber drawing of a preform may have a slightly different profile.

The disclosed step-index transmission fiber includes a central core having an index difference (Dn₁) with an outer optical cladding, which acts as an optical cladding; a first intermediate inner cladding having an index difference (Dn₂) with the outer optical cladding; a first depressed inner cladding having a index difference (Dn₃) with the outer optical cladding; a second intermediate inner cladding having an index difference (Dn₄) with the outer optical cladding and a second depressed inner cladding having a index difference Dn₅ with the outer optical cladding. The index difference (Dn₅) is in absolute value less than the index difference (Dn₃). The refractive indexes in the central core, in the first and second depressed inner claddings, and in the first and second intermediate inner claddings are substantially constant over the whole of their widths. The set profile is a step-index fiber. The width of the core is defined by its radius (r₁) and the width of the claddings is defined by their respective outer radii, (i.e., r₂−r₅).

In order to define a set index profile for an optical fiber, the index value of the outer cladding is generally taken as a reference. FIG. 18 shows only a small part of the outer optical cladding and is intended to schematically illustrate the index differences in the core. The outer optical cladding of substantially constant index stretches out until the outside of the optical fiber. In other words, there is no further optical cladding having different refractive indices outside of the outer optical cladding. The index values for the central core, the depressed inner claddings, and the intermediate claddings are then shown as index differences (Dn_(1,2,3,4,5)) Generally, the outer optical cladding consists of silica, but this cladding may be doped in order to increase or reduce its refractive index, (e.g., to change the propagation characteristics of the signal).

The Table (below) provides typical limiting values for the radii and the index differences that allow a fiber profile to be achieved so that the fiber has reduced bending losses while meeting the criteria for optical propagation from the G.652 standard for transmission fibers. The r values correspond to set fiber profiles:

TABLE 6 r₂ r₄ r₅ Dn₁ Dn₁-Dn₂ Dn₃ Dn₅ r₁ (μm) (μm) r₃ (μm) (μm) (μm) (10⁻³) (10⁻³) (10⁻³) (10⁻³) min 35 9.0 14.0 18.0 25.0 5.0 4.5 −5 −0.3 max 4.5 12.0 16.0 20.0 40.0 5.6 6.0 −15 −3

The presence of the second depressed inner cladding (r₅, Dn₅), which is less depressed than the first depressed inner cladding, provides a limitation of the presence of leakage modes capable of propagating along the fiber and inducing an increase in the effective cut-off wavelength. By the presence of the first intermediate inner cladding (r₂, Dn₂), it is possible to ensure proper confinement of the single mode signal in the central core and to retain a mode field diameter compatible with the G.652 standard. By the presence of the first, deeply depressed inner cladding (r₃, Dn₃) the bending losses may be further reduced.

The transmission fiber disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1, having an index profile such as described previously, has reduced bending losses at wavelengths of use.

In particular, for a wavelength of 1625 nanometers, the disclosed fiber has bending losses less than or equal to 0.1 dB for a winding of 100 turns around a spool with a bending radius of 20 millimeters; bending losses less than or equal to 0.1 dB for a winding of 10 turns around a spool with a bending radius of 15 millimeters; bending losses less than or equal to 0.2 dB for a winding of one turn around a spool with a bending radius of 10 millimeters; bending losses than or equal to 0.5 dB for a winding of one turn around a spool with a bending radius of 7.5 millimeters; bending losses than or equal to 1 dB for a winding of one turn around a spool with a bending radius of 5 millimeters.

The disclosed fiber has even smaller bending losses at the wavelength of 1550 nanometers. In particular, for a wavelength of 1550 nanometers, the fiber has bending losses less than or equal to 0.02 dB for a winding of 10 turns around a spool with a bending radius of 15 millimeters; bending losses less than or equal to 0.05 dB for a winding of one turn around a spool or a bending radius of 10 millimeters; bending losses less than or equal to 0.2 dB for a winding of one turn around a spool with a bending radius of 7.5 millimeters.

Further, the disclosed fiber also has reduced microbending losses as compared with an SSMF. The microbending losses may be estimated with a so-called grid test (10 needles of 1.5 millimeters) at the wavelength of 1550 nanometers. This test uses a grid, formed with ten polished needles with a diameter of 1.5 millimeters, and spaced apart by 1 cm. The fiber passes through the grid over two passages, orthogonally to the axis of the needles. The fiber and the grid are pressed between two rigid plates covered with a layer of about 3 millimeters of high density polyethylene foam. The layers of the assembly (i.e., plates, grids, fiber) are positioned horizontally and the whole is covered with a 250 gram mass. With this test, the fiber has microbending losses less than or equal to 0.025 dB at 1550 nanometers.

Microbending losses may also be estimated by the so-called fixed diameter drum method at a wavelength of 1625 nanometers. This method is described in the technical recommendation of the International Electrotechnical Commission from subcommittee 86A under reference IEC TR-62221. The diameter of the drum used is 60 cm; the drum is covered with extra fine sand paper. With this method, the disclosed fiber has microbending losses less than or equal to 0.8 dB/km at 1625 nanometers.

Further, the disclosed fiber meets the criteria of the G.652 standard.

In particular, it has an effective cut-off wavelength (λ_(ceff)) less than 1330 nanometers so that the cable cut-off wavelength (λ_(CC)) is less than 1260 nanometers, in compliance with the G.652 standard. The disclosed fiber also has an MFD between 8.6 microns and 9.5 microns for a wavelength of 1310 nanometers.

The disclosed fiber may also have a MAC ratio of up to about 8.2. The yield for manufacturing this fiber is therefore better because there is no longer any requirement to exclusively select fibers with a MAC less than 7.9.

FIG. 19 graphically illustrates the bending losses at 1625 nanometers versus the bending radius for a SSMF, for a fiber identical with the fiber disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1, but without the second depressed section, and for two fibers as disclosed in U.S. Patent Application Publication No. US 2007/0280615 A1.

A first curve (3A) shows the bending losses of a step-index SSMF. This fiber has a MAC of 8.1. It is noted that for small bending radii less than 7.5 millimeters, the bending losses considerably increase and exceed the value of 1 dB for a winding of one turn. Such a conventional fiber, currently used for long distance transmissions, is therefore not very suited for an FFTH or FTTC application as it may neither be wound in a miniature box of an optical module nor be subject to possible accidental bendings related to the installation without inducing strong optical losses.

A second curve (3B) shows the bending losses of a fiber without any second depressed section. This fiber has a MAC of 8.2 and meets the criteria of the G.652 standard. It is noted that for small bending radii less than 7.5 millimeters, the bending losses are less than 1 dB/turn. On the other hand, the bending losses remain relatively significant for larger bending radii. Thus, the fiber has bending losses of the order of 0.5 dB for a winding of ten turns around a spool with a radius equal to 20 millimeters and of the order of 0.4 dB for a winding of 100 turns around a spool with a radius equal to 20 millimeters. These bending loss values for bending radii of 15 millimeters and 20 millimeters do not allow this fiber to be used in storage boxes with such winding radii.

A third curve (3C) shows the bending losses of a fiber as disclosed. The fiber corresponding to this curve has a MAC of 8.2 and meets the criteria of the G.652 standard. It is noted that for small bending radii, less than 7.5 millimeters, the bending losses are of the order of 0.4 dB/turn, less than the preferred maximum value of 0.5 dB/turn; and for a bending radius of 10 millimeters, the disclosed fiber has bending losses of the order of 0.2 dB/turn (i.e., the targeted upper limiting value). Also, for larger bending radii, bending losses remain limited; thus, for a bending radius of 15 millimeters, the fiber has bending losses of the order of 0.04 dB/10 turns, less than the preferred maximum value of 0.1 dB/10 turns; and for a bending radius of 20 millimeters, the disclosed fiber has bending losses of the order of 0.03 dB/100 turns, less than the preferred maximum value of 0.1 dB/100 turns.

A fourth curve (3D) shows the bending losses of another fiber according to U.S. Patent Application Publication No. US 2007/0280615 A1. The fiber corresponding to this curve has a MAC of 8.1 and meets the criteria of the G.652 standard. It is noted that for small bending radii less than 7.5 millimeters, the bending losses are of the order of 0.1 dB/turn, less than the preferred maximum value of 0.5 dB/turn; and for a bending radius of 10 millimeters, the disclosed fiber has bending losses of the order of 0.07 dB/turn, less than the preferred maximum value of 0.2 dB/turn. Also, for larger bending radii, the bending losses remain limited; thus, for a bending radius of 15 millimeters, the disclosed fiber has bending losses of the order of 0.04 dB/10 turns, less than the preferred maximum value of 0.1 dB/10 turns; and for a bending radius of 20 millimeters, the disclosed fiber has bending losses of the order of 0.01 dB/100 turns, less than the preferred maximum value of 0.01 dB/100 turns.

Yet another exemplary bend-insensitive glass fiber for use in the present invention is disclosed in U.S. Patent Application Publication No. US 2008/0152288 A1 and its related U.S. patent application Ser. No. 11/999,333 for an Optical Fiber (Flammer et al.), now U.S. Pat. No. 7,555,186. As noted, each of these commonly assigned patent documents is incorporated by reference in its entirety. Combining (i) a bend-insensitive glass fiber having the refractive index profile as disclosed in U.S. Patent Application Publication No. US 2008/0152288 A1 and a coating according to the present invention can achieve optical fibers having exceptional reductions in microbend sensitivity.

The bend-insensitive glass fiber disclosed in U.S. Patent Application Publication No. US 2008/0152288 A1 (i.e., the “disclosed fiber”) possesses (i) a core having a radius r₁ that includes at least two core dopants, wherein the core has a refractive index difference Δn₁ with an outer optical cladding (e.g., an external optical cladding); (ii) a first inner cladding (i.e., an intermediate cladding) having a radius r₂ and a refractive index difference Δn₂ with the outer cladding; and (iii) a depressed, second inner cladding (i.e., a depressed trench) having a radius r₃ and a refractive index difference Δn₃ with the outer cladding of less than −3×10⁻³; and wherein the radial concentration of at least one of the core dopants varies substantially continuously over the core region.

According to exemplary embodiments, the disclosed fiber may include one or more of the following additional features:

-   -   The radial concentration of at least one of the core dopants         varies continuously over the entire core region;     -   The radial concentration of each of at least two core dopants         varies continuously over the entire core region;     -   The radial variation of at least one core dopant concentration         is such that its first derivative is proportional to the radial         power fraction P(r) of the optical signal transmitted in the         optical fiber;     -   The optical fiber has, at a wavelength of 1550 nanometers, a         spontaneous Brillouin spectrum width greater than or equal to         100 MHz;     -   The variation of at least one core dopant concentration         corresponds to an refractive index variation greater than or         equal to 1×10⁻³;     -   The core dopants are selected from germanium (Ge), fluorine (F),         phosphorus (P), aluminum (Al), chlorine (Cl), boron (B),         nitrogen (N), and/or alkali metals;     -   One of the core dopants is germanium (Ge), the germanium         concentration varying radially in the core between about 1 and         20 weight percent based upon the core's total composition (i.e.,         mass). In other words, at any position within the core, the         germanium concentration ranges between 1 and 20 weight percent         (i.e., a radial concentration of about 1-20 weight percent         germanium).     -   One of the core dopants is fluorine (F), the fluorine         concentration varying radially in the core between about 0.3 and         8 weight percent based upon the core's total composition (i.e.,         mass). In other words, at any position within the core, the         fluorine concentration ranges between 0.3 and 8 weight percent         (i.e., a radial concentration of about 0.3-8 weight percent         fluorine).     -   One of the core dopants is phosphorus (P), the phosphorus         concentration varying radially in the core between about 1 and         10 weight percent based upon the core's total composition (i.e.,         mass). In other words, at any position within the core, the         phosphorus concentration ranges between 1 and 10 weight percent         (i.e., a radial concentration of about 1-10 weight percent         phosphorus).     -   The depressed, second inner cladding includes germanium in a         radial concentration of between 0.5 weight percent and 7 weight         percent based upon the second inner cladding's total composition         (i.e., mass). Stated differently, at any position within the         second inner cladding, the germanium concentration is between         about 0.5 and 7 weight percent.     -   The refractive index difference Δn₃ between the second inner         cladding and the outer cladding is greater than about −15×10⁻³;     -   The optical fiber has, at a wavelength of 1550 nanometers, an         effective area greater than or equal to 50 μm²;     -   The optical fiber has, at a wavelength of 1550 nanometers, an         attenuation less than or equal to 0.3 dB/km;     -   The optical fiber has, at a wavelength of 1625 nanometers,         bending losses that are less than about 0.1 dB for a winding of         ten turns around a bend radius of 15 millimeters; less than         about 0.2 dB for a winding of one turn around a bend radius of         10 millimeters; and less than about 0.5 dB for a winding of one         turn around a bend radius of 7.5 millimeters;     -   The optical fiber has, at a wavelength of 1550 nanometers,         bending losses that are less than about 0.02 dB for a winding of         ten turns around a bend radius of 15 millimeters; less than         about 0.05 dB for a winding of one turn around a bend radius of         10 millimeters; and less than about 0.2 dB for a winding of one         turn around a bend radius of 7.5 millimeters;     -   The optical fiber has, up to a wavelength of 1625 nanometers,         microbending losses, measured by the so-called fixed diameter         drum method, of 0.8 dB/km or less.

In one aspect (and with reference to FIG. 20), the bend-insensitive glass fiber disclosed in U.S. Patent Application Publication No. US 2008/0152288 A1, includes a core 11 (i.e., the central core region in which the optical signal to be transmitted is guided) and a cladding region for confining the optical signal in the core 11. The cladding region includes a first inner cladding 12, a depressed trench 13 (or depressed, second inner cladding), and an outer cladding 14 (e.g., an external optical cladding). The depressed trench 13 typically has a refractive index difference with the outer cladding 14 that is less than −3×10⁻³ (e.g., less than about −15×10⁻³).

The core region of the disclosed fiber includes at least two dopants, the concentrations of which, in effect, vary continuously over the entire radius of the core region. Typically, the substantially continuous variation in radial dopant concentration is progressive (e.g., increasing continuously in a radial direction) or regressive (e.g., decreasing continuously in a radial direction). That said, the radial dopant concentration can both increase and decrease in a radial direction.

The variation of the first dopant (e.g., germanium) is compensated by variation of the second dopant (e.g., fluorine) to obtain a predetermined refractive index profile of the core region. The core region remains longitudinally homogeneous along the optical fiber (i.e., concentrations of the core dopants are constant along the optical fiber's length).

As will be appreciated by those having ordinary skill in the art, depending on the application, the optical fiber has a target refractive index profile that is defined according to various parameters (i.e., mode field diameter, chromatic dispersion parameters, effective cut-off wavelength, and effective area).

Variation of dopant concentration in the optical fiber's radial direction, particularly in its core, broadens the Brillouin spectrum and thereby increases the Brillouin threshold. A smooth dopant variation ensures uniform mode power distribution for the different dopant concentrations and limits fiber losses. Use of at least two dopants in the optical fiber facilitates the achievement of a target refractive index profile and reduces the impact of SBS reduction on other optical parameters, particularly mode field diameter and chromatic dispersion parameters. The disclosed fiber possesses a refractive index profile that meets the aforementioned G.652 standard.

FIG. 14 depicts a nominal refractive index profile of an exemplary single-mode transmission optical fiber. As schematically depicted in FIG. 20, the exemplary optical fiber 10 includes (i) a central core 11 having refractive index difference Δn₁ with an outer cladding 14; (ii) a first inner cladding 12 (i.e., an intermediate cladding) having a refractive index difference Δn₂ with the outer cladding 14; and (iii) a depressed trench 13 having an a refractive index difference Δn₃ with the outer cladding 14. The width of the core 11 is defined by its radius r₁ and the widths of the claddings by their respective outer radii r₂ and r₃.

To define a nominal refractive index profile for an optical fiber, the index of the outer cladding is generally taken as a reference. The index values of the central core and of the claddings are then provided as index differences (i.e., Δn_(1,2,3)) with the outer cladding. Generally, the outer cladding is formed of silica, but may be doped to increase or reduce its refractive index, such as to modify the signal propagation characteristics.

Each section of the refractive index profile of the optical fiber can therefore be defined using integrals that associate the variations in refractive indexes with the radius of each fiber section. See FIG. 20.

Three integrals thus can be defined for the optical fiber, which represent the core surface I₁, the surface of the first inner cladding I₂ and the surface of the depressed, second inner cladding I₃. In this regard, the expression “surface” is not to be interpreted geometrically (i.e., structurally) but should be understood instead to describe the area under the curve (i.e., r·Δn) such as depicted in FIG. 14.

These three integrals can be expressed as follows:

I₁ = ∫₀^(r 1)Δ n(r)⋅ 𝕕r ≈ r₁ × Δ n 1 I₂ = ∫_(r 1)^(r 2)Δ n(r)⋅ 𝕕r ≈ (r₂ − r₁) × Δ n 2 I₃ = ∫_(r 2)^(r 3)Δ n(r)⋅ 𝕕r ≈ (r₃ − r₂) × Δ n 3

Table 7 (below) gives the limit values of radii and refractive index differences, and the limit values of the integral I₁ that are required so that the optical fiber shows reduced bending losses and microbending losses while meeting the optical propagation criteria of standard G.652 for transmission fibers. The values provided in Table 7 are the nominal profiles of exemplary optical fibers.

TABLE 7 r₂ r₃ Δn₁ Δn₂ Δn₃ Δn₁-Δn₂ I₁ r₁ (μm) (μm) (μm) r₁/r₂ (10⁻³) (10⁻³) (10⁻³) (10⁻³) (μm · 10⁻³) Min 3.5 7.5 12.0 0.27 4.2 −1.2 −15 3.9 17 Max 4.5 14.5 25.0 0.5 6.2 1.2 −3 5.9 24

The integral I₁ of the central core influences the shape and size of the fundamental propagation mode of the signal in the optical fiber. An integral value for the central core of between 17×10⁻³ microns and 24×10⁻³ microns makes it possible in particular to maintain a mode field diameter that is compatible with the G.652 standard. In addition, the depressed trench Δn₃ makes it possible to improve bending losses and microbending losses in SSMF.

The core region of the disclosed fiber includes at least two dopants whose respective concentrations vary substantially continuously over essentially the entire core region while maintaining the core region's pre-determined refractive index profile. Those having ordinary skill in the art will appreciate that radial dopant concentration might be unchanged over small increments (i.e., radial segments). That said, as a practical matter, radial dopant concentration typically varies continuously over the core radius. See FIGS. 21 b-21 c.

As noted, this allows broadening the Brillouin spectrum and thereby increases the Brillouin threshold. Because the dopant concentration variation is compensated so as to keep a pre-determined refractive index profile, notably in the core region, the optical propagation criteria of the G.652 standard are not jeopardized by the presence of at least two dopants in the core. Moreover, the first inner cladding (Δn₂, r₂) ensures that the optical power remains in the core region without the depressed trench (Δn₃, r₃) adversely impacting optical power throughput.

For a signal propagating at a wavelength of 1550 nanometers, the disclosed fiber has a spontaneous Brillouin spectrum width that is at least about 100 MHz. Such a broadened Brillouin spectrum effectively increases the Brillouin threshold by at least a factor of two (or by about three dB in logarithmic scale) as compared to a standard single mode fiber (SSMF). The disclosed fiber achieves a much higher Brillouin threshold compared to standard transmission fibers with limited fiber loss (e.g., less than 0.3 dB/km at a wavelength of 1550 nanometers) without significant change to the optical transmission parameters.

The first core dopant (e.g., germanium) is chosen to achieve strong and continuous variations in density and elasticity in the fiber material. According to one embodiment, the radial distribution of the first dopant concentration C_(d)(r) is such that its first derivative is proportional to the radial power fraction P(r) of the optical signal transmitted in the fiber in accordance with the following equation (in which a is a constant):

$\frac{\mathbb{d}{C_{d}(r)}}{\mathbb{d}r} = {\alpha \cdot {P(r)}}$

This radial power fraction P(r) is expressed in watt per meters, the integral of which is equal to the total transmitted power P according to the following relationship: ∫P(r)dr=P

According to another embodiment, the depressed trench (i.e., the second inner cladding) can include germanium at a concentration of between about 0.5 and 7 weight percent, typically in a concentration of less than about 1.5 weight percent (e.g., between about 0.5 and 1.5 weight percent), even if the index needs to be less than −3×10⁻³. The presence of germanium in the depressed trench modifies the viscosity of silica and the depressed trench's elasto-optical coefficient, thereby improving microbending sensitivity.

FIGS. 21 a, 21 b, and 21 c relate to an exemplary optical fiber as disclosed. The optical fiber of FIGS. 21 a-21 c possesses a step-core profile. The core has a given constant refractive index value; the depressed trench is separated from the core by an intermediate inner cladding (i.e., the first inner cladding). FIG. 21 a illustrates the exemplary optical fiber's refractive index profile using arbitrary units.

Turning to FIG. 21 b and FIG. 21 c, the core region of the fiber includes a first dopant, germanium (Ge), which is known to increase the value of the refractive index of silica, and a second dopant, fluorine (F), which is known to decrease the value of the refractive index of silica. FIG. 21 b and FIG. 21 c illustrate dopant concentrations in weight percent. The concentration of at least one of the core dopants varies essentially continuously over the entire core region.

With respect to the exemplary optical fiber depicted in FIGS. 21 a, 21 b, and 21 c, both dopants vary continuously (and progressively) over the entire core region. The use of at least two dopants ensures that the core refractive index profile is maintained to a nominal profile such to achieve desirable optical transmission characteristics. Indeed, because the second dopant can compensate for the refractive index variation introduced by the variation of concentration of the first dopant, a target refractive index profile can be achieved.

The variation of at least one core dopant concentration introduces density and elasticity variation in the optical fiber section that broadens the Brillouin spectrum and thereby increases the Brillouin threshold. The variation of core dopant concentration should be large enough to introduce sufficient density and elasticity variation in order to reduce SBS.

The inventors have achieved satisfactory results if at least one of the core dopants has a concentration variation over the entire core region that corresponds to a refractive index variation that is at least about 1×10⁻³ (i.e., variation in core dopant concentration sufficient to achieve this refractive index variation if not compensated by another core dopant). In other words, the variation in first dopant concentration (i.e., between the maximum and minimum radial dopant concentrations) should be such that, without compensation by a second dopant, a refractive index variation of at least about 1×10⁻³ would be achieved in the core.

As schematically depicted in FIGS. 21 b-21 c, the germanium concentration varies progressively from 5.8 weight percent to 12 weight percent, and the fluorine concentration varies progressively from 0.1 weight percent to 1.7 weight percent.

The smooth and regular variation of dopant concentration ensures uniform mode power distribution for the different dopant concentration and limits fiber losses. Simulations performed on an optical fiber exemplified in FIGS. 21 a, 21 b, and 21 c gives, at a signal wavelength of 1550 nanometers, a spontaneous Brillouin spectrum width larger than 100 MHz and an increased SBS threshold power (i.e., increased by at least a factor of two compared as compared to a standard single mode fiber), and a limited Rayleigh loss increase of about 0.013 dB/km. Despite this Rayleigh loss increase, the disclosed fiber maintains compliance with the G.652 standard, having attenuation losses of less than about 0.3 dB/km at 1550 nanometers.

As noted, FIGS. 21 a, 21 b, and 21 c represent one example of the disclosed fiber. Dopants other than germanium (Ge) and fluorine (F) can be used to achieve an optical fiber with reduced SBS. In this regard, the core region includes at least two dopants that may be selected from germanium (Ge), fluorine (F), phosphorus (P), aluminum (Al), chlorine (Cl), boron (B), nitrogen (N), and/or alkali metals. To the extent one of the core dopants is germanium (Ge), the concentration typically falls between about one and 20 weight percent; to the extent one of the core dopants is fluorine (F), the concentration is typically less than ten weight percent (e.g., between about 0.3 and eight weight percent); to the extent one of the core dopants is phosphorus (P) the concentration typically falls between about one and ten weight percent.

The exemplary optical fiber represented in FIGS. 21 a-21 c possesses a depressed trench to reduce its sensitivity to bending losses. The disclosed fiber therefore combines low bending losses and high Brillouin threshold.

Conventionally, starting from the teaching of J. Botineau et al. in “Effective Stimulated Brillouin Gain in Single Mode Optical Fibers,” Electronics Letters, Vol. 31, No. 23 (1995), one having ordinary skill in the art would choose a refractive index profile with triangular shape or parabolic shape to increase the Brillouin threshold and might apply an external trench to reduce bending losses. This conventional approach, however, renders compliance with the G.652 specifications difficult.

FIG. 22 compares four different kinds of refractive index profile shapes: a typical step refractive index profile without trench (i.e., SSMF); a step-core refractive index profile with a trench in the cladding (e.g., the optical fiber of FIGS. 21 a-21 c); a triangular core refractive index profile with a trench in the cladding; and a parabolic core profile with a trench in the cladding. For each, numerous refractive index profiles with different core diameter and maximum dopant level were simulated.

FIG. 22 depicts the zero dispersion wavelength 4 and the slope of the dispersion at the zero dispersion wavelength. The rectangle area indicates the parameters of the G.652 specifications for those optical characteristics. Fiber profiles having too high cut-off wavelengths and non-conforming nominal mode-field diameter at 1310 nanometers so as to be non-compliant with the G.652 specifications were omitted.

FIG. 22 shows that adding a depressed trench to a SSMF profile restricts the profile flexibility for production and thus increases fiber rejection rate. Using a triangular core refractive index profile with a trench in the cladding results in optical fibers that do not meet the G.652 requirements. A parabolic core refractive index profile with a trench in the cladding does yields some optical fibers within the G.652 specifications, but the zone of tolerance is narrow and many rejects would be expected.

The bend-insensitive glass fiber disclosed in U.S. Patent Application Publication No. US 2008/0152288 A1 achieves reduced bending and microbending losses, as well as a much higher Brillouin threshold, compared to standard transmission optical fibers. The disclosed fiber may be used in a receiver module of a FTTH system or in a transmitter module to input high power signals into a telecommunication system, or in a high bit-rate long-haul optical transmission cable, with reduced optical losses. Moreover, the disclosed fiber is compatible with marketed systems as it meets standard G.652.

In one embodiment, the disclosed fiber exhibits, at a wavelength of 1310 nanometers, a chromatic dispersion slope of 0.092 ps/(nm²·km) or less; a cancellation of chromatic dispersion at a wavelength of between 1300 and 1324 nanometers; and a cabled cut-off wavelength of 1260 nanometers or less.

In another embodiment, the disclosed fiber has, at a wavelength of 1550 nanometers, an effective area superior or equal to 50 μm², typically 80 μm², and attenuation at 1550 nanometers of less than or equal to 0.3 dB/km. Such optical fiber according to this embodiment is suitable for use in data transmission in telecommunication systems.

In this regard, an exemplary optical transmission system may include an optical transmitter emitting optical signals in a predetermined range of wavelength, a transmission optical fiber, and an optical receiver receiving the optical signal with improved signal-to-noise ratio (SNR) due to reduced SBS and limited increase in fiber losses (e.g., attenuation). As compared to conventional systems, the optical transmitter may input into the optical fiber an optical signal with higher power, the Brillouin threshold power for the transmission optical fiber being increased by at least a factor of two compared with a conventional SMF.

In yet another embodiment, the disclosed fiber has, at a wavelength of 1625 nanometers, improved bending losses as follows: less than about 0.1 dB for a winding of ten turns around a bend radius of 15 millimeters; less than about 0.2 dB for a winding of one turn around a bend radius of ten millimeters; and less than about 0.5 dB for a winding of one turn around a bend radius of 7.5 millimeters.

Likewise, the disclosed fiber has, at a wavelength of 1550 nanometers, improved bending losses as follows: less than about 0.02 dB for a winding of ten turns around a bend radius of 15 millimeters; less than about 0.05 dB for a winding of one turn around a bend radius of ten millimeters; and less than about 0.2 dB for a winding of one turn around a bend radius of 7.5 millimeters.

Moreover, for wavelengths of up to 1625 nanometers, the disclosed fiber demonstrates microbending losses of less than about 0.8 dB/km measured by the so-called fixed diameter drum method. Accordingly, such optical fiber is suitable for implementation in optical modules or storage boxes for use in FTTH or FTTC systems.

Yet another exemplary bend-insensitive glass fiber for use in the present invention is disclosed in U.S. Patent Application No. 61/112,006 for a Bend-Insensitive Single-Mode Optical Fiber (de Montmorillon et al.) and its related patent application Ser. No. 12/436,423, now published as U.S. Patent Application Publication No. US 2009/0279835 A1. As noted, each of these commonly assigned patent documents is incorporated by reference in its entirety. Combining (i) a bend-insensitive glass fiber having the refractive index profile as disclosed in U.S. Patent Application No. 61/112,006 and coating according to the present invention can achieve optical fibers having virtually negligible sensitivity to microbend-inducing stresses.

The bend-insensitive glass fiber disclosed in U.S. Patent Application No. 61/112,006 (i.e., the “disclosed fiber”) includes a central core, an intermediate cladding, and a depressed trench. The refractive index profile is optimized to improve the bending losses by a factor of ten relative to the constraints imposed by the G.657B standard, while retaining a mode field diameter compatible with the G.652 standard and ensuring a sufficient attenuation of the LP11 mode.

In particular, the surface of the core, as well as the surface and the volume of the depressed trench, are optimized to improve the bending losses considerably. The surface of the core or the surface of the depressed trench should not extend geometrically but should correspond to values taking two dimensions into account—the product of the radius and the index difference. Similarly, the volume of the depressed trench corresponds to a value taking three dimensions into account—the product of the square of the radius and the index difference.

The disclosed fiber includes, from its center toward its periphery, a central core, an intermediate cladding, a depressed trench, and an external optical cladding. The central core has a radius r₁ and a positive index difference Δn₁ with the external optical cladding. The intermediate cladding has a radius r₂ and a positive index difference Δn₂ with the external optical cladding. The difference Δn₂ is less than the index difference Δn₁ of the core. The depressed trench has a radius r₃ and a negative index difference Δn₃ with the external optical cladding. The disclosed fiber is further characterized in that it has (i) a mode field diameter (MFD) between 8.6 microns and 9.5 microns at a wavelength of 1310 nanometers and (ii) bending losses less than 0.25×10⁻³ dB/turn for a radius of curvature of 15 millimeters and a wavelength of 1550 nanometers. The length of fiber required for the attenuation of the LP11 mode to reach 19.3 dB at a wavelength of 1260 nanometers is less than 90 meters.

According to one fiber embodiment, the surface integral of the central core (V₀₁), defined as

V₀₁ = ∫₀^(r 1)Δ n(r)⋅ 𝕕r ≈ r₁ × Δ n₁, is between 20.0×10⁻³ microns and 23.0×10⁻³ microns. The surface integral of the depressed trench (V₀₃), defined as

V₀₃ = ∫_(r 2)^(r 3)Δ n(r) ⋅ 𝕕r ≈ (r₃ − r₂) × Δ n₃, is between −55.0×10⁻³ microns and −30.0×10⁻³ microns. The volume integral of the depressed trench (V₁₃), defined as,

V₁₃ = 2 ⋅ ∫_(r 2)^(r 3)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₃² − r₂²) × Δ n₃, is between −1200×10⁻³ μm² and −750×10⁻³ μm².

In preferred embodiments, the fiber has physical properties and operational parameters with improved resistance to bending losses. For instance, the fiber has an effective cut-off wavelength λ_(ceff) greater than 1350 nanometers, the effective cut-off wavelength being measured as the wavelength at which the optical signal becomes single mode after propagation over two meters of fiber. The fiber has, for a wavelength of 1550 nanometers, bending losses less than or equal to 7.5×10⁻³ dB/turn for a radius of curvature of 10 millimeters, bending losses less than or equal to 0.05 dB/turn for a radius of curvature of 7.5 millimeters, and bending losses less than 0.15 dB/turn for a radius of curvature of 5 millimeters.

The fiber disclosed herein also shows reduced bending losses at higher wavelengths. For example, at a wavelength of 1625 nanometers, the fiber has bending losses less than 1.5×10⁻³ dB/turn for a radius of curvature of 15 millimeters, bending losses less than or equal to 25×10⁻³ dB/turn for a radius of curvature of 10 millimeters, bending losses less than or equal to 0.08 dB/turn for a radius of curvature of 7.5 millimeters, and bending losses less than 0.25 dB/turn for a radius of curvature of 5 millimeters. Accordingly, in a preferred embodiment, the fiber has a cut-off wavelength between 1300 nanometers and 1400 nanometers, with the cutoff wavelength measured as the wavelength at which the optical signal is no longer single mode after propagation over 5 meters of fiber. Cut-off wavelength is distinguished from cable cut-off, measured as the wavelength at which the attenuation of the LP11 mode is greater than or equal to 19.3 dB after propagation over 22 meters of fiber. The fiber has a cable cut-off wavelength between 1250 nanometers and 1300 nanometers.

A third measurement at issue here is the theoretical cut-off wavelength measured as the wavelength from which the LP11 mode is propagated in leaky mode. In one embodiment, the fiber has a theoretical cut-off wavelength less than or equal to 1250 nanometers. The fiber has an attenuation of the LP11 mode greater than 5 dB after propagation over 22 meters of fiber at a wavelength of 1260 nanometers.

The operational parameters described above result from preferred physical properties of the fiber. In one embodiment, the central core of the fiber has a radius between 3.8 microns and 4.35 μm; the intermediate cladding has a radius between 8.5 microns and 9.7 μm; the depressed trench has a radius between 13.5 microns and 16 μm, which can be less than or equal to 15 μm, and the central core has an index difference with the external optical cladding between 5.3×10⁻³ and 5.7×10⁻³.

As noted above, the refractive index profile of a fiber is plotted in terms of the difference between refractive index values at points on the radius of the fiber and the external optical cladding. The intermediate cladding has an index difference with the optical cladding between 0.1×10⁻³ and 0.6×10⁻³. The depressed trench has an index difference with the optical cladding between −10.0×10⁻³ and −5.0×10⁻³. The fiber has a zero chromatic dispersion wavelength between 1300 nanometers and 1324 nanometers; the fiber has a chromatic dispersion slope value at the zero chromatic dispersion wavelength of less than 0.092 ps/(nm²·km).

As depicted in FIG. 23, the bend-insensitive glass fiber (10) disclosed in U.S. Patent Application No. 61/112,006 has a central core (11), an intermediate cladding (12) and a depressed cladding (13). For purposes herein, depressed cladding means a radial portion of the fiber (10) having a refractive index less than the index of the external optical cladding (14). Typically, the central core (11), the intermediate cladding (12), and the depressed cladding (13) are obtained by chemical vapor deposition in a silica tube. The external optical cladding (14) includes the silica tube and the overcladding on the tube. In preferred embodiments, the overcladding is generally natural or doped silica, but can also be obtained by any other deposition technique ((vapor axial deposition (“VAD”) or outside vapor deposition (“OVD”)).

FIG. 24 illustrates a refractive index profile for the transmission fiber (10) of FIG. 23. The profile of FIG. 24 is a set profile, i.e., representative of the theoretical profile of the fiber, but the fiber actually obtained after fiber drawing of a preform may have a slightly different profile.

In a manner known in the art per se, an optical fiber (10) is obtained by preform drawing. By way of example, the preform may be a very high-quality glass tube (pure silica) which eventually forms part of the external optical cladding (14). The external optical cladding (14) surrounds the central core (11) and the internal claddings (12, 13) of the fiber (10). This tube can then be overcladded to increase its diameter before going through the fiber-drawing operation on a fiber-drawing tower. For the production of the preform, the tube is generally mounted horizontally and held at both ends by glass bars on a lathe; then the tube is rotated and heated locally for the deposition process determining the composition of the preform. This composition determines the optical characteristics of the future fiber.

The fiber includes a central core (11) having an index difference Δn₁ with an external cladding (14) functioning as an optical cladding. The fiber (10) further includes an intermediate cladding (12) having an index difference Δn₂ with the external optical cladding (14) and a depressed trench cladding (13) having an index difference Δn₃ with the external optical cladding (14). The refractive indexes in the central core (11), the intermediate cladding (12) and the depressed trench (13) are substantially constant throughout their respective widths, as set forth in FIG. 24. FIG. 23 illustrates that the width of the core (11) is defined by its radius r₁ and the width of the claddings by their respective external radii, r₂, and r₃. The external optical cladding is denoted as r₄.

In order to define a set refractive index profile for an optical fiber, the index value of the external optical cladding is generally taken as a reference (n_(g)). The index values of the central core (11), the intermediate cladding (12), and the depressed trench cladding (13) are then presented in FIG. 24 as index differences Δn_(1,2,3). Generally, the external optical cladding (14) is composed of silica but this cladding can be doped to increase or reduce its refractive index—for example, to modify the propagation characteristics of the signal.

Each fiber profile section shown in FIG. 24 (21-24) can also be defined on the basis of integrals that link the index variations with the radius of each section of the fiber (10). It is thus possible to define three surface integrals for the disclosed fiber (10), representative of the surface of the core V₀₁, the surface of the intermediate cladding V₀₂ and the surface of the depressed trench V₀₃. The expression “surface” is not to be understood geometrically but corresponds to a value taking two dimensions into account.

These three surface integrals can be expressed as follows:

V₀₁ = ∫₀^(r 1)Δ n(r) ⋅ 𝕕r ≈ r₁ × Δ n₁ V₀₂ = ∫_(r 1)^(r 2)Δ n(r) ⋅ 𝕕r ≈ (r₂ − r₁) × Δ n₂ V₀₃ = ∫_(r 2)^(r 3)Δ n(r) ⋅ 𝕕r ≈ (r₃ − r₂) × Δ n₃.

Similarly, it is possible to define three volume integrals for the disclosed fiber (10), representative of the volume of the core V₁₁, the volume of the intermediate cladding V₁₂ and the volume of the depressed trench V₁₃. The expression “volume” is not to be understood geometrically but corresponds to a value taking three dimensions into account. These three volume integrals can be expressed as follows:

V₁₁ = 2 ⋅ ∫₀^(r 1)Δ n(r) ⋅ r ⋅ 𝕕r ≈ r₁² × Δ n₁ V₁₂ = 2 ⋅ ∫_(r 1)^(r 2)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₂² − r₁²) × Δ n₂ V₁₃ = 2 ⋅ ∫_(r 2)^(r 3)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₃² − r₂²) × Δ n₃.

Table 8 (below) shows 30 examples of fiber profiles according to preferred embodiments in comparison with three SSMF fiber profiles and one fiber profile corresponding to the G.657A and G.657B standards (noted as “BIF” for Bend Insensitive Fiber). As noted, Draka Comteq markets bend-insensitive optical fibers having excellent resistance to bending losses under the trade name BendBright^(XS)®. The values in the tables correspond to the set profiles for each fiber.

The first column of Table 8 assigns a reference to each example; the next three columns give the values of the radii of the core (11), the intermediate cladding (12), and the depressed trench (13), respectively. The next three columns give the corresponding values of the index differences with the external optical cladding (14). The index values are measured at a wavelength of 633 nanometers. Table 8 also shows the surface integral and volume integral values of the core (11), the intermediate cladding (12) and the depressed trench (13), as defined above.

TABLE 8 V₀₁ V₀₂ V₀₃ V₁₁ V₁₂ V₁₃ r₁ r₂ r₃ Dn₁ Dn₂ Dn3 (μm) (μm) (μm) (μm²) (μm²) (μm²) (μm) (μm) (μm) [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] BIF 3.93 9.38 14.72 5.26 0.13 −5.01 20.7 0.7 −26.8 81.1 9.4 −645 SSMF1 4.35 13.92 5.00 −0.20 21.8 −1.9 0.0 94.6 −35.0 0 SSMF2 4.51 13.92 5.00 −0.20 22.5 −1.9 0.0 101.5 −34.7 0 SSMF3 4.55 13.92 5.24 −0.20 23.8 −1.9 0.0 108.4 −34.6 0 Ex 1 3.97 9.38 14.25 5.56 0.11 −9.74 22.1 0.6 −47.4 87.7 8.3 −1120 Ex 2 3.98 8.65 13.83 5.52 0.21 −9.56 22.0 1.0 −49.5 87.3 12.6 −1113 Ex 3 4.01 8.95 14.39 5.38 0.20 −9.27 21.6 1.0 −50.4 86.5 13.1 −1177 Ex 4 3.98 8.77 13.79 5.56 0.33 −9.25 22.1 1.6 −46.5 87.9 19.9 −1049 Ex 5 3.90 8.70 14.31 5.58 0.44 −7.93 21.8 2.1 −44.5 84.8 26.6 −1024 Ex 6 4.03 9.17 14.04 5.45 0.21 −9.62 21.9 1.1 −46.8 88.3 14.0 −1087 Ex 7 4.04 8.61 14.39 5.56 0.15 −7.05 22.4 0.7 −40.7 90.5 8.7 −937 Ex 8 3.83 8.94 13.92 5.69 0.52 −8.51 21.8 2.6 −42.4 83.7 33.8 −969 Ex 9 4.01 8.97 14.39 5.38 0.39 −8.45 21.6 1.9 −45.8 86.4 25.1 −1071 Ex 10 3.84 9.30 14.38 5.49 0.48 −9.38 21.1 2.6 −47.7 81.0 34.2 −1129 Ex 11 3.82 9.01 13.55 5.67 0.57 −9.63 21.7 2.9 −43.7 82.8 37.7 −986 Ex 12 4.03 8.84 14.28 5.30 0.11 −9.52 21.3 0.5 −51.8 85.9 6.6 −1197 Ex 13 3.96 8.61 13.86 5.58 0.31 −7.87 22.1 1.4 −41.3 87.6 17.9 −928 Ex 14 3.92 8.78 13.84 5.55 0.32 −8.75 21.7 1.5 −44.3 85.2 19.7 −1002 Ex 15 3.88 9.09 14.35 5.62 0.34 −7.84 21.8 1.8 −41.2 84.5 23.1 −965 Ex 16 4.02 9.65 14.35 5.37 0.14 −9.72 21.6 0.8 −45.7 86.7 10.6 −1097 Ex 17 4.01 9.19 14.39 5.32 0.36 −8.74 21.3 1.9 −45.4 85.6 24.9 −1072 Ex 18 3.93 9.30 14.48 5.30 0.51 −7.76 20.8 2.7 −40.1 81.7 36.0 −955 Ex 19 3.93 9.26 13.53 5.34 0.51 −9.74 21.0 2.7 −41.6 82.3 36.0 −949 Ex 20 3.93 9.25 13.53 5.31 0.50 −9.93 20.8 2.7 −42.5 81.9 35.3 −967 Ex 21 3.93 9.28 14.47 5.31 0.53 −7.51 20.9 2.8 −39.0 82.0 37.5 −926 Ex 22 3.93 8.50 15.00 5.48 0.50 −5.00 21.5 2.3 −32.5 84.6 28.4 −764 Ex 23 3.93 9.25 13.65 5.37 0.50 −9.90 21.1 2.7 −43.5 83.0 35.1 −997 Ex 24 3.93 8.50 15.50 5.33 0.51 −5.00 21.0 2.3 −35.0 82.4 28.8 −840 Ex 25 3.93 9.27 13.65 5.31 0.52 −9.80 20.9 2.8 −42.9 82.1 36.9 −983 Ex 26 3.94 8.50 15.00 5.43 0.50 −5.00 21.4 2.3 −32.5 84.3 28.6 −764 Ex 27 3.94 9.25 13.54 5.30 0.56 −9.87 20.9 3.0 −42.3 82.3 39.2 −964 Ex 28 3.94 9.26 13.50 5.33 0.51 −9.88 21.0 2.7 −41.9 82.8 35.5 −954 Ex 29 3.95 9.29 13.91 5.30 0.50 −8.93 20.9 2.7 −41.2 82.6 35.4 −957 Ex 30 3.93 8.50 15.50 5.32 0.57 −5.00 20.9 2.6 −35.0 82.1 32.2 −840

The disclosed fiber (10) is a step-index fiber comprising a central core (11), an intermediate cladding (12) and a depressed trench (13). It is noted from Table 8 that the central core (11) has a radius r₁ between 3.8 microns and 4.35 microns and preferably between 3.8 microns and 4.05 μm, i.e., narrower than the core of an SSMF fiber. The fiber (10) has an index difference Δn₁ (21) with the external optical cladding (14) between 5.3×10⁻³ and 5.7×10⁻³, i.e., greater than an SSMF fiber. The surface integral of the core V₀₁ is between 20.0×10⁻³ microns and 23.0×10⁻³ μm, and the volume integral of the core V₁₁ is between 81×10⁻³ μm² and 91×10⁻³ μm².

It is also noted from Table 8 that the disclosed fiber has a depressed trench (13). The depressed trench (13) has a large volume and makes it possible to greatly limit the bending losses. Table 8 thus shows that the depressed trench (13) has a radius r₃ between 13.5 microns and 16 microns and an index difference Δn₃ (23) with the external optical cladding (14) between −10.0×10⁻³ and −5.0×10⁻³.

Table 8 also shows that the surface integral of the depressed trench V₀₃, as defined above, is between −55.0×10⁻³ microns and −30.0×10⁻³ μm, and the volume integral of the depressed trench V₁₃, as defined above, is between −1200×10⁻³ μm² and −750×10⁻³ μm².

According to a preferred embodiment, the radius of the depressed cladding r₃ can be limited to 15 microns to further reduce the cost of production of the fiber (only the examples 24 and 30 have a depressed cladding with a radius greater than 15 μm). In fact, the depressed trench (13) can be produced by plasma chemical vapor deposition (PCVD) making it possible to incorporate a large quantity of fluorine in the silica to form deeply depressed claddings. The part of the fiber (10) corresponding to the tube and to the PCVD deposition is, however, the most expensive; it is therefore sought to limit this part as much as possible. It is also possible to envisage producing the depressed trench (13) by incorporation of micro-holes or micro-bubbles rather than by fluorine doping. Fluorine doping, however, remains easier to control for industrial production than the incorporation of micro-bubbles.

A depressed trench (13) corresponding to the surface and volume criteria defined above makes it possible to achieve a good compromise between greatly reduced bending losses relative to the existing fibers and a sufficiently consistent leakage regime of the LP11 mode at a wavelength of 1260 nanometers.

As is clear from Table 11, which is discussed in detail hereafter, the disclosed fiber has bending losses which are ten times (10×) smaller than the limits imposed by the G.657B standard. On the other hand, the disclosed fiber does not strictly comply with the G.657 standard in terms of cut-off wavelength. As is clear from Table 10, which is also discussed in detail hereafter, the disclosed fiber has an effective cut-off wavelength λ_(ceff) greater than 1350 nanometers and a cable cut-off wavelength λ_(ceff), between 1250 nanometers and 1300 nanometers. Nevertheless, the fiber disclosed herein ensures that the higher order LP11 modes are propagated in the 1260 nanometers leaky mode regime.

It is also noted from Table 8 that a preferred embodiment of the fiber has an intermediate cladding (12) between the central core (11) and the depressed trench (13). This intermediate cladding (12) makes it possible to limit the effects of the depressed trench (13) on the propagation of the optical signal in the core. Table 8 shows that the intermediate cladding (12) has a radius r₂ between 8.5 microns and 9.7 microns and an index difference Δn₂ (22) with the optical cladding between 0.1×10⁻³ and 0.6×10⁻³. Table 8 shows that the surface integral of the intermediate cladding V₀₂, as defined above, is between 0.5×10⁻³ microns and 3.0×10⁻³ microns. The volume integral of the intermediate cladding V₁₂, as defined above, is between 6×10⁻³ μm² and 40×10⁻³ μm².

The central core (11) of the disclosed fiber (10) is optimized, in combination with the intermediate cladding (12), to guarantee parameters of optical transmission in the fiber in conformity with the G.652 and G657A standards, particularly in terms of mode field diameter and chromatic dispersion. This also helps ensure compatibility with fibers of other optical systems.

Table 9 (below) shows the optical transmission characteristics for exemplary fibers. The first column repeats the references of Table 8. The following columns provide, for each fiber profile, the mode field diameter (MFD) values for wavelengths of 1310 nanometers and 1550 nanometers, zero dispersion wavelength (ZDW) and zero dispersion slope (ZDS).

TABLE 9 MFD1310 MFD1550 ZDW ZDS (μm) (μm) (nm) ps/(nm² · km) BIF 8.80 9.90 1320 0.0878 SSMF1 9.14 10.31 1314 0.0855 SSMF2 9.27 10.39 1309 0.0871 SSMF3 9.18 10.25 1306 0.088 Ex 1 8.63 9.62 1314 0.0899 Ex 2 8.64 9.56 1308 0.0924 Ex 3 8.76 9.71 1310 0.0918 Ex 4 8.69 9.63 1309 0.0921 Ex 5 8.68 9.66 1313 0.0914 Ex 6 8.76 9.73 1310 0.0913 Ex 7 8.66 9.58 1307 0.0916 Ex 8 8.64 9.65 1317 0.0904 Ex 9 8.86 9.84 1311 0.0918 Ex 10 8.76 9.81 1319 0.0901 Ex 11 8.67 9.68 1317 0.0908 Ex 12 8.75 9.69 1308 0.0923 Ex 13 8.65 9.59 1310 0.0917 Ex 14 8.66 9.62 1312 0.0914 Ex 15 8.64 9.65 1317 0.0897 Ex 16 8.79 9.81 1314 0.0898 Ex 17 8.89 9.90 1312 0.0913 Ex 18 8.95 10.01 1317 0.0905 Ex 19 8.91 9.94 1315 0.0913 Ex 20 8.92 9.95 1315 0.0914 Ex 21 8.96 10.02 1317 0.0905 Ex 22 8.80 9.81 1314 0.0906 Ex 23 8.89 9.91 1315 0.0913 Ex 24 8.88 9.91 1314 0.0909 Ex 25 8.94 9.97 1315 0.0914 Ex 26 8.83 9.84 1313 0.0908 Ex 27 8.97 10.00 1314 0.0917 Ex 28 8.93 9.95 1314 0.0915 Ex 29 8.95 9.99 1315 0.0911 Ex 30 8.92 9.95 1314 0.0911

It is noted from Table 9 that the disclosed fiber (10) is compatible with fibers corresponding to the criteria of the G.652 standard. In particular, the fiber disclosed herein has a mode field diameter MFD in the standardized range of values from 8.6 microns to 9.5 microns at 1310 nanometers, a zero dispersion wavelength between 1300 nanometers and 1324 nanometers, and a zero dispersion slope of less than 0.092 ps/(nm²·km). Each of these values is in accordance with the G.652 standard.

On the other hand, as shown by Table 10 (below), the fiber has an effective cut-off wavelength λ_(ceff) greater than 1350 nanometers. As discussed above, the cut-off wavelength is measured as being the wavelength at which the optical signal is no longer single mode after propagation over two meters of fiber, as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-44 standard. This increased effective cut-off wavelength value leads to a cable cut-off wavelength value λ_(ceff) between 1250 nanometers and 1300 nanometers. The cable cut-off wavelength is measured as the wavelength at which the optical signal is no longer single mode after propagation over 22 meters of fiber, as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard. The optical signal is single mode when the attenuation of the LP11 mode is greater than or equal to 19.3 dB. The G.652 and G.657 standards both impose a maximum value of 1260 nanometers for the cable cut-off wavelength.

One purpose of the developments disclosed herein is to produce fibers that can be used on all of the transmission bandwidths exploited by optical systems, i.e., fibers that can be used in single mode propagation from the original bandwidth (OB) which extends from 1260 nanometers to 1360 nanometers, and as far as the ultra-long (UL) bandwidth beyond 1625 nanometers. A low cut-off wavelength makes it possible to guarantee the possibility of using the fiber over all of the available bandwidths.

The simulations of Table 10 (below), however, show that the directly higher order LP11 mode is propagated according to a leaky mode from a wavelength of 1260 nanometers. The fiber disclosed herein can, therefore, be used in single mode transmission over the original bandwidth (OB: 1260 nanometers to 1360 nanometers).

Table 10 (below) shows several cut-off wavelength values for the disclosed fibers. The first column of Table 10 repeats the references of Table 8.

The column “Theoretical Fiber Cutoff” provides a theoretical cut-off wavelength value, which corresponds to the transition wavelength between a guided propagation of the LP11 mode and a propagation in leaky mode of this LP11 mode. For working wavelengths beyond this effective cut-off wavelength, the LP11 mode is propagated in leaky mode.

The column “Standard Fiber Cutoff” corresponds to the effective cut-off wavelength λ_(ceff) as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard.

The column “5 m Fiber Cutoff” corresponds to the cut-off wavelength measured as the wavelength at which the optical signal is no longer single mode after propagation over 5 meters of fiber. This value therefore corresponds to the effective cut-off wavelength measured after propagation over 5 meters of fiber instead of 2 meters of fiber.

The column “Standard Cable Cutoff” corresponds to the cable cut-off wavelength λ_(cc) as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard. According to the recommendation of Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard, the cable cut-off wavelength λ_(cc) is determined by positioning the fiber into two 40 millimeters radius loops and by arranging the remainder of the fiber (i.e., 21.5 meters of fiber) on a mandrel with a radius of 140 millimeters.

The column “Straight Cable Cutoff” corresponds to the cable cut-off wavelength by positioning the fiber into two loops, each having a 40 millimeter radius, and by arranging the remainder of the fiber (i.e., 21.5 meters of fiber) virtually straight.

The column “LP11 LL @1260 after 22 m” indicates the leakage losses of the LP11 mode after propagation over 22 meters of virtually straight fiber.

The column “Length—19.3 dB LP11 LL @1260 nanometers” indicates the length of fiber required to achieve leakage losses of the LP11 mode equal to 19.3 dB with the fiber being kept virtually straight. This indicates at which distance the fiber, arranged virtually straight, is single mode within the meaning of the G.652 and G.657 standards.

TABLE 10 Length- Straight LP11 LL 19.3 dB Fiber Cutoff Std Fiber 5-m Fiber Std Cable Cable @1260 nm LP11 LL (theory) Cutoff Cutoff Cutoff Cutoff after 22 m @1260 nm (nm) (nm) (nm) (nm) (nm) (dB) (m) BIF 1197 1270 1234 1196 1208 180 2 SSMF1 1287 1226 1226 1151 1151 2 212 SSMF2 1334 1267 1267 1188 1188 0 >1000 SSMF3 1381 1311 1311 1231 1231 0 >1000 Ex 1 Ex 1 1235 1437 1366 1290 1284 9 48 Ex 2 1231 1438 1368 1287 1284 9 45 Ex 3 1228 1466 1392 1297 1301 7 61 Ex 4 1250 1420 1354 1290 1283 6 69 Ex 5 1243 1419 1353 1287 1280 10 44 Ex 6 1246 1430 1361 1292 1285 8 56 Ex 7 1248 1403 1343 1284 1278 8 52 Ex 8 1249 1386 1326 1274 1270 11 40 Ex 9 1250 1436 1367 1297 1291 5 89 Ex 10 1233 1435 1362 1287 1280 10 42 Ex 11 1250 1379 1321 1271 1268 10 41 Ex 12 1213 1467 1393 1300 1298 9 48 Ex 13 1243 1383 1323 1271 1266 16 27 Ex 14 1232 1397 1333 1271 1265 16 26 Ex 15 1239 1392 1331 1272 1267 15 28 Ex 16 1234 1424 1354 1283 1277 11 39 Ex 17 1244 1429 1360 1291 1284 9 49 Ex 18 1242 1382 1322 1268 1264 18 24 Ex 19 1243 1360 1304 1257 1258 26 16 Ex 20 1238 1362 1305 1256 1255 24 17 Ex 21 1247 1376 1319 1267 1266 15 28 Ex 22 1249 1351 1302 1259 1262 18 23 Ex 23 1246 1378 1319 1268 1264 17 25 Ex 24 1235 1373 1317 1264 1260 18 24 Ex 25 1243 1371 1313 1263 1260 22 20 Ex 26 1247 1350 1300 1257 1260 22 19 Ex 27 1248 1367 1310 1263 1263 17 25 Ex 28 1245 1362 1306 1259 1259 24 18 Ex 29 1244 1371 1314 1264 1260 20 21 Ex 30 1240 1375 1319 1267 1263 17 24

It is noted from Table 10 that the standard effective cut-off wavelength λ_(fi), i.e., as measured according to the recommendations of Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard, is greater than 1350 nanometers. Similarly, it is noted from Table 10 that the standard cable cut-off wavelength λ_(cc), i.e., as measured according to the recommendations of Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-44 standard, is between 1250 nanometers and 1300 nanometers, i.e., often greater than the limit of 1260 nanometers imposed by the G.652 and G.657 standards.

It is, however, noted from Table 10 that the LP11 mode is nevertheless highly attenuated from a wavelength of 1260 nanometers. In fact, the “theoretical” cut-off wavelength is less than or equal to 1250 nanometers. Thus, the higher order LP11 mode is propagated in a leaky mode regime in the original bandwidth, and only the fundamental mode remains guided in the disclosed fiber as from a wavelength of 1260 nanometers.

Similarly, it is noted from Table 10 that the fiber cut-off wavelength is significantly reduced after only 5 meters of propagation in the fiber. Thus, the cut-off wavelength, measured as the wavelength at which the optical signal is no longer single mode after propagation over 5 meters of fiber, is between 1300 nanometers and 1400 nanometers for the disclosed fiber.

Moreover, Table 10 clearly shows that the LP11 mode is already well attenuated after 22 meters of propagation. It is noted in particular that the attenuation of the LP11 mode in an exemplary disclosed fiber (10) is greater than the attenuation of the LP11 mode in an SSMF fiber when the fiber is arranged virtually straight. In fact, in an SSMF fiber, it is the bends that make it possible to highly attenuate the LP11 mode. Thus, the fiber has an attenuation of the LP11 mode greater than 5 dB after 22 meters of propagation in straight fiber at a wavelength of 1260 nanometers.

Moreover, Table 10 also shows that the attenuation of at least 19.3 dB of the LP11 mode is achieved relatively rapidly, after less than 90 meters, instead of the 22 meters imposed by the standards.

Thus, the failure to comply in the strictest sense with the G.652 and G.657 standards in terms of cut-off wavelength is minimized by the fact that the higher order LP11 mode is sufficiently attenuated from a wavelength of 1260 nanometers so as not to impair the quality of the propagation of the fundamental mode.

Moreover, the increase in the effective cut-off wavelength makes it possible to increase the value of the MAC as defined above and consequently to reduce the bending losses.

Table 11 (below) reports bending loss values for preferred embodiments of fibers as disclosed herein. The first column of Table 11 repeats the references of Table 8. The next four columns show bending loss values PPC for respective radii of curvature of 15 millimeters, 10 millimeters, 7.5 millimeters, and 5 millimeters at a wavelength of 1550 nanometers. The next four columns give bending loss values PPC for respective radii of curvature of 15 millimeters, 10 millimeters, 7.5 millimeters, and 5 millimeters at a wavelength of 1625 nanometers.

The last column has a factor of merit FOM representing the order of magnitude of the improvement in the bending losses by the disclosed fibers relative to the limits imposed by the G.657B standard. The FOM of Table 11 is thus defined as an average of the ratios between the upper limits imposed by the G.657B standard and the bending losses in the disclosed fibers for each radius of curvature measured.

Table 11 reports on the first line the bending loss limit values imposed by the G.657B standard for each radius of curvature and for the wavelengths of 1550 nanometers and 1625 nanometers.

TABLE 11 R = 15 mm R = 10 mm R = 7.5 mm R = 5 mm R = 15 mm R = 10 mm R = 7.5 mm R = 5 mm PPC @1550 nm (dB/turn) PPC @1625 nm (dB/turn) FOM G657B 0.003 0.1 0.5 0.01 0.2 1 1.00 BIF 1.3E−03 2.9E−02 1.0E−01 3.3E−01 7.0E−03 8.4E−02 2.3E−01 6.3E−01 0.70 SSMF1 1.5E−02 6.0E−01 3.4E+00 1.7E+01 7.5E−02 1.7E+00 6.9E+00 2.7E+01 8.44 SSMF2 6.3E−03 3.6E−01 2.4E+00 1.4E+01 3.4E−02 1.0E+00 5.0E+00 2.3E+01 5.21 SSMF3 9.6E−04 1.1E−01 1.0E+00 8.9E+00 6.5E−03 3.6E−01 2.5E+00 1.4E+01 2.45 Ex 1 4.3E−05 2.0E−03 9.7E−03 3.6E−02 3.3E−04 7.3E−03 2.5E−02 7.0E−02 0.04 Ex 2 4.4E−05 2.0E−03 9.2E−03 3.5E−02 3.4E−04 7.2E−03 2.4E−02 7.1E−02 0.04 Ex 3 6.4E−05 2.2E−03 9.0E−03 3.2E−02 4.4E−04 7.6E−03 2.3E−02 6.4E−02 0.04 Ex 4 3.6E−05 2.0E−03 1.1E−02 4.5E−02 2.9E−04 7.6E−03 2.8E−02 8.8E−02 0.04 Ex 5 4.7E−05 2.4E−03 1.2E−02 4.6E−02 3.6E−04 8.6E−03 3.1E−02 9.2E−02 0.04 Ex 6 5.3E−05 2.4E−03 1.2E−02 4.4E−02 3.9E−04 8.6E−03 3.0E−02 8.4E−02 0.04 Ex 7 4.2E−05 2.4E−03 1.3E−02 5.1E−02 3.4E−04 8.9E−03 3.3E−02 1.0E−01 0.04 Ex 8 4.5E−05 2.6E−03 1.5E−02 6.3E−02 3.6E−04 9.9E−03 3.8E−02 1.2E−01 0.05 Ex 9 6.9E−05 2.8E−03 1.3E−02 4.8E−02 4.8E−04 9.7E−03 3.2E−02 9.1E−02 0.05 Ex 10 8.3E−05 3.0E−03 1.3E−02 4.7E−02 5.6E−04 1.0E−02 3.2E−02 8.8E−02 0.06 Ex 11 4.9E−05 2.9E−03 1.6E−02 7.1E−02 3.9E−04 1.1E−02 4.2E−02 1.3E−01 0.05 Ex 12 9.1E−05 2.6E−03 9.5E−03 3.0E−02 6.1E−04 8.6E−03 2.3E−02 6.1E−02 0.06 Ex 13 5.4E−05 2.9E−03 1.6E−02 6.5E−02 4.3E−04 1.1E−02 4.1E−02 1.3E−01 0.05 Ex 14 6.6E−05 3.0E−03 1.5E−02 5.6E−02 5.0E−04 1.1E−02 3.8E−02 1.1E−01 0.05 Ex 15 6.2E−05 3.1E−03 1.5E−02 6.3E−02 4.7E−04 1.1E−02 3.9E−02 1.2E−01 0.06 Ex 16 9.8E−05 3.5E−03 1.4E−02 5.3E−02 6.5E−04 1.2E−02 3.5E−02 1.0E−01 0.07 Ex 17 1.0E−04 3.6E−03 1.5E−02 5.6E−02 6.7E−04 1.2E−02 3.7E−02 1.0E−01 0.07 Ex 18 2.2E−04 6.9E−03 2.7E−02 1.0E−01 1.3E−03 2.1E−02 6.4E−02 1.8E−01 0.13 Ex 19 2.0E−04 7.1E−03 3.1E−02 1.1E−01 1.2E−03 2.3E−02 7.2E−02 2.1E−01 0.12 Ex 20 2.2E−04 7.4E−03 3.1E−02 1.1E−01 1.4E−03 2.4E−02 7.2E−02 2.1E−01 0.14 Ex 21 2.1E−04 7.1E−03 2.9E−02 1.1E−01 1.3E−03 2.2E−02 6.9E−02 2.0E−01 0.13 Ex 22 1.4E−04 6.5E−03 3.1E−02 1.3E−01 1.0E−03 2.2E−02 7.7E−02 2.4E−01 0.11 Ex 23 1.4E−04 5.4E−03 2.4E−02 9.0E−02 9.2E−04 1.8E−02 5.8E−02 1.7E−01 0.09 Ex 24 2.3E−04 7.3E−03 2.8E−02 1.0E−01 1.4E−03 2.3E−02 6.8E−02 2.0E−01 0.14 Ex 25 2.0E−04 6.8E−03 2.9E−02 1.0E−01 1.2E−03 2.2E−02 6.8E−02 2.0E−01 0.12 Ex 26 1.7E−04 7.4E−03 3.4E−02 1.3E−01 1.2E−03 2.4E−02 8.2E−02 2.5E−01 0.12 Ex 27 2.0E−04 7.1E−03 3.0E−02 1.1E−01 1.2E−03 2.3E−02 7.1E−02 2.1E−01 0.12 Ex 28 1.9E−04 7.0E−03 3.0E−02 1.1E−01 1.2E−03 2.3E−02 7.2E−02 2.1E−01 0.12 Ex 29 2.0E−04 7.0E−03 2.9E−02 1.0E−01 1.3E−03 2.2E−02 6.8E−02 2.0E−01 0.13 Ex 30 2.3E−04 7.4E−03 2.9E−02 1.1E−01 1.4E−03 2.3E−02 7.0E−02 2.1E−01 0.14

It is noted from Table 11 that the bending losses of the disclosed fibers are clearly less than the limits imposed by the G.657B standard.

Thus, the fiber disclosed above has, for a wavelength of 1550 nanometers, bending losses less than 0.25×10⁻³ dB/turn for a radius of curvature of 15 millimeters, as compared to a limit of 3×10⁻³ dB/turn imposed by the G.657B standard. The fiber further has bending losses less than or equal to 7.5×10⁻³ dB/turn for a radius of curvature of 10 millimeters, as compared against a limit of 0.1 dB/turn imposed by the G.657B standard. The bending losses are less than or equal to 0.05 dB/turn for a radius of curvature of 7.5 millimeters, as against a limit of 0.5 dB/turn imposed by the G.657B standard, and bending losses less than 0.15 dB/turn for a radius of curvature of 5 millimeters.

The bending losses at a wavelength of 1550 nanometers in the disclosed fiber have been improved by a factor greater than 10× relative to the limits of the G.657B standard.

Similarly, the disclosed fiber exhibits, for a wavelength of 1625 nanometers, bending losses less than 1.5×10⁻³ dB/turn for a radius of curvature of 15 millimeters, as compared to a limit of 10×10⁻³ dB/turn imposed by the G.657B standard. The bending losses are less than or equal to 25×10⁻³ dB/turn for a radius of curvature of 10 millimeters, as compared to a limit of 0.2 dB/turn imposed by the G.657B standard. The fiber exhibits bending losses less than or equal to 0.08 dB/turn for a radius of curvature of 7.5 millimeters, as against a limit of 1 dB/turn imposed by the G.657B standard, and bending losses less than 0.25 dB/turn for a radius of curvature of 5 millimeters.

The bending losses at a wavelength of 1625 nanometers in the disclosed fiber have been improved by a factor of 10 relative to the limits of the G.657B standard. It should be noted that, within the framework of an industrial production of optical fiber preforms, the conformity tests, vis-à-vis the standards, are carried out by taking into account only significant figures indicated in the standard. Thus, when the G.657B standard imposes the limit value of 0.01 dB/turn at a wavelength of 1625 nanometers for a radius of curvature of 15 millimeters, the manufacturer will tolerate bending losses ranging up to 0.014 dB/turn at this wavelength for this radius of curvature. Bending losses less than 1.5×10⁻³ dB/turn for a radius of curvature of 15 millimeters at a wavelength of 1625 nanometers are therefore at least ten times better than the limits imposed by the standard.

The column FOM of Table 11 shows that the disclosed fibers have clearly improved bending losses relative to the existing BIF fibers, which correspond to the requirements of the G.657B standard.

The fibers disclosed herein are well suited to a use in optical systems installed in the subscriber's home, of FTTH type, in which the fiber is subjected to significant bend stresses due to the miniaturization of the optical box or holding the fiber in place with staples. The fiber can be placed in particularly compact optical boxes. In fact, the optical fiber may be arranged with a radius of curvature of less than 15 millimeters, for example, a radius of curvature about 5 millimeters. The fiber remains compatible with the fibers of existing systems, in particular in terms of mode field diameter for good fiber-to-fiber coupling. The increase in the cut-off wavelength is not detrimental due to a significant attenuation of the LP11 mode from a wavelength of 1260 nanometers.

Yet another exemplary bend-insensitive glass fiber for use in the present invention is disclosed in U.S. Patent Application No. 61/112,374 for a Bend-Insensitive Single Mode Optical Fiber (de Montmorillon et al.) and its related patent application Ser. No. 12/436,484, now published as U.S. Patent Application Publication No. US 2009/0279836 A1. As noted, each of these commonly assigned patent documents is incorporated by reference in its entirety. Combining (i) a bend-insensitive glass fiber having the refractive index profile as disclosed in U.S. Patent Application No. 61/112,374 and coating according to the present invention can achieve optical fibers having virtually negligible sensitivity to microbend-inducing stresses.

The bend-insensitive glass fiber disclosed in U.S. Patent Application No. 61/112,374 (the “disclosed fiber”) includes a central core, an intermediate cladding, and a depressed trench that is surrounded by an external optical cladding. The refractive index profile is optimized to improve the bending losses by a factor of ten relative to the constraints imposed by the G.657B recommendation, while retaining a mode field diameter compatible with the G.652 recommendation and ensuring a sufficient attenuation of the LP11 mode.

In particular, the surface of the core, as well as the surface and the volume of the depressed trench, are optimized to improve the bending losses considerably. The surface of the core or the surface of the depressed trench should not extend geometrically but should correspond to values taking two dimensions into account—the product of the radius and the index difference. Similarly, the volume of the depressed trench corresponds to a value taking three dimensions into account—the product of the square of the radius and the index difference.

The disclosed fiber includes, from its center toward is periphery, a central core, an intermediate cladding, a depressed trench, and an external optical cladding. The central core has a radius r₁ and a positive index difference Δn₁ with the external optical cladding. The intermediate cladding has a radius r₂ and an index difference Δn₂ with the external optical cladding. The difference Δn₂ is less than the index difference Δn₁ of the core. The depressed trench has a radius r₃ and a negative index difference Δn₃ with the external optical cladding. The disclosed fiber is further characterized in that it has (i) a nominal mode field diameter (MFD) between 8.6 microns and 9.5 microns at a wavelength of 1310 nanometers and (ii) bending losses less than 0.15 dB/turn for a radius of curvature of 5 millimeters at a wavelength of 1550 nanometers and a cable cut-off wavelength of less than or equal to 1260 nanometers, measured as the wavelength at which the attenuation of the LP11 mode is greater than or equal to 19.3 dB after propagation over 22 meters of fiber, the fiber being either straight conditioned or conditioned around a 140-millimeter curvature radius mandrel.

According to one fiber embodiment, the surface integral of the central core (V₀₁), defined as

V₀₁ = ∫₀^(r 1)Δ n(r) ⋅ 𝕕r ≈ r₁ × Δ n₁, is between 19.0×10⁻³ microns and 23.0×10⁻³ microns and preferably between 20.0×10⁻³ microns and 23.0×10⁻³ microns. In a further preferred embodiment, the surface integral of the central core (V₀₁) is between 20.0×10⁻³ microns and 21.5×10⁻³ μm, which gives rise to outstanding optical properties.

According to one fiber embodiment, the surface integral of the depressed trench (V₀₃), defined as

V₀₃ = ∫_(r 2)^(r 3)Δ n(r) ⋅ 𝕕r ≈ (r₃ − r₂) × Δ n₃, is between −55.0×10⁻³ microns and −30.0×10⁻³ microns. In a further preferred embodiment the surface integral of the depressed trench (V₀₃) is between −42.5×10⁻³ microns and −32.5×10⁻³ μm, which gives rise to outstanding optical properties.

According to one fiber embodiment, the volume integral of the depressed trench (V₁₃), defined as,

V₁₃ = 2 ⋅ ∫_(r 2)^(r 3)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₃² − r₂²) × Δ n₃, is between −1200×10⁻³ μm² and −750×10⁻³ μm². In a further preferred embodiment the volume integral of the depressed trench (V₁₃) is between −1000×10⁻³ μm² and −750×10⁻³ μm², which gives rise to outstanding optical properties of the present fiber.

In preferred embodiments, the fiber has physical properties and operational parameters with improved resistance to bending losses. For instance, the fiber has an effective cut-off wavelength λ_(ceff) greater than 1300 nanometers, the effective cut-off wavelength being measured as the wavelength at which the optical signal becomes single mode after propagation over two meters of fiber. The fiber has, for a wavelength of 1550 nanometers, bending losses less than or equal to 0.003 dB/turn for a radius of curvature of 15 millimeters, bending losses less than or equal to 3×10⁻² dB/turn, preferably 7.5×10⁻³ dB/turn for a radius of curvature of 10 millimeters, bending losses less than or equal to 0.05 dB/turn for a radius of curvature of 7.5 millimeters, and bending losses less than 0.15 dB/turn, preferably less than 0.10 dB/turn for a radius of curvature of 5 millimeters.

The fiber disclosed herein also shows reduced bending losses at higher wavelengths. For example, at a wavelength of 1625 nanometers, the fiber has bending losses less than 10⁻² dB/turn, preferably less than 1.5×10⁻³ dB/turn for a radius of curvature of 15 millimeters, bending losses less than or equal to 0.1 dB/turn, preferably less than or equal to 25×10⁻³ dB/turn for a radius of curvature of 10 millimeters, bending losses less than or equal to 0.15 dB/turn, preferably less than or equal to 0.08 dB/turn for a radius of curvature of 7.5 millimeters, and bending losses less than or equal to 0.25 dB/turn for a radius of curvature of 5 millimeters.

Accordingly, in a preferred embodiment, the fiber has a cut-off wavelength between 1240 nanometers and 1310 nanometers, with the cut-off wavelength measured as the wavelength at which the optical signal is no longer single mode after propagation over five meters of fiber. Cut-off wavelength is distinguished from cable cut-off, measured as the wavelength at which the attenuation of the LP11 mode is greater than or equal to 19.3 dB after propagation over 22 meters of fiber. The fiber has a cable cut-off wavelength less than or equal to 1260 nanometers.

A fourth cut-off definition at issue here is the theoretical cut-off wavelength defined as the wavelength from which the LP11 mode is propagated in leaky mode. In one embodiment, the fiber has a theoretical cut-off wavelength less than or equal to 1250 nanometers. The fiber has an attenuation of the LP11 mode greater than 5 dB after propagation over 22 meters of fiber at a wavelength of 1260 nanometers.

The operational parameters described above result from preferred physical properties of the fiber. In one embodiment, the central core of the fiber has a radius between 3.8 microns and 4.35 μm; the intermediate cladding has a radius between 8.5 microns and 9.7 μm; the depressed trench has a radius between 13.5 microns and 16 μm, which can be less than or equal to 15 microns. The central core typically has a refractive index difference (Δn₁) with the external optical cladding between 4.9×10⁻³ and 5.7×10⁻³.

As noted, the refractive index profile of a fiber is plotted in terms of the difference between refractive index values at points on the radius of the fiber and the external optical cladding. The intermediate cladding has an index difference with the optical cladding between −0.1×10⁻³ and 0.6×10⁻³. The depressed trench has an index difference with the optical cladding between −10.0×10⁻³ and −5.0×10⁻³. The fiber has a zero chromatic dispersion wavelength between 1300 nanometers and 1324 nanometers; the fiber has a chromatic dispersion slope value at the zero chromatic dispersion wavelength of less than 0.092 ps/(nm²·km).

As depicted in FIG. 23, the bend-insensitive glass fiber (10) disclosed in U.S. Patent Application No. 61/112,374 has a central core (11), an intermediate cladding (12) and a depressed cladding (13). For purposes herein, depressed cladding means a radial portion of the fiber (10) having a refractive index less than the refractive index of the external optical cladding (14). Typically, the central core (11), the intermediate cladding (12), and the depressed cladding (13) are obtained by chemical vapor deposition in a silica tube. The external optical cladding (14) includes the silica tube and the overcladding on the tube. In preferred embodiments, the overcladding is generally natural or doped silica, but can also be obtained by any other deposition technique ((vapor axial deposition (“VAD”) or outside vapor deposition (“OVD”)).

FIG. 24 illustrates a refractive index profile for the transmission fiber (10) of FIG. 23. The profile of FIG. 24 is a set profile, i.e., representative of the theoretical profile of the fiber, but the fiber actually obtained after fiber drawing of a preform may have a slightly different profile.

In a manner known in the art per se, an optical fiber (10) is obtained by preform drawing. By way of example, the preform may be a very high-quality glass tube (pure silica) which eventually forms part of the external optical cladding (14). The external optical cladding (14) surrounds the central core (11) and the internal claddings (12, 13) of the fiber (10). This tube can then be overcladded to increase its diameter before going through the fiber-drawing operation on a fiber-drawing tower. For the production of the preform, the tube is generally mounted horizontally and held at both ends by glass bars on a lathe; then the tube is rotated and heated locally for the deposition process determining the composition of the preform. This composition determines the optical characteristics of the future fiber.

The fiber includes a central core (11) having an index difference Δn₁ with an external cladding (14) functioning as an optical cladding. The fiber (10) further includes an intermediate cladding (12) having an index difference Δn₂ with the external optical cladding (14) and a depressed trench cladding (13) having an index difference Δn₃ with the external optical cladding (14). The refractive indexes in the central core (11), the intermediate cladding (12) and the depressed trench (13) are substantially constant throughout their respective widths, as set forth in FIG. 24. FIG. 23 illustrates that the width of the core (11) is defined by its radius r₁ and the width of the claddings by their respective external radii, r₂ and r₃. The external optical cladding is denoted as r₄.

In order to define a set refractive index profile for an optical fiber, the refractive index value of the external optical cladding is generally taken as a reference (n_(g)). The index values of the central core (11), the intermediate cladding (12), and the depressed trench cladding (13) are then presented in FIG. 24 as index differences Δn_(1,2,3). Generally, the external optical cladding (14) is composed of silica but this cladding can be doped to increase or reduce its refractive index—for example, to modify the propagation characteristics of the signal.

Each fiber profile section shown in FIG. 24 (21-24) can also be defined on the basis of integrals that link the index variations with the radius of each section of the fiber (10). It is thus possible to define three surface integrals for the disclosed fiber (10), representative of the surface of the core V₀₁, the surface of the intermediate cladding V₀₂ and the surface of the depressed trench V₀₃. The expression “surface” is not to be understood geometrically but corresponds to a value taking two dimensions into account. These three surface integrals can be expressed as follows:

V₀₁ = ∫₀^(r 1)Δ n(r) ⋅ 𝕕r ≈ r₁ × Δ n₁ V₀₂ = ∫_(r 1)^(r 2)Δ n(r) ⋅ 𝕕r ≈ (r₂ − r₁) × Δ n₂ V₀₃ = ∫_(r 2)^(r 3)Δ n(r) ⋅ 𝕕r ≈ (r₃ − r₂) × Δ n₃.

Similarly, it is possible to define three volume integrals for the disclosed fiber (10), representative of the volume of the core V₁₁, the volume of the intermediate cladding V₁₂ and the volume of the depressed trench V₁₃. The expression “volume” is not to be understood geometrically but corresponds to a value taking three dimensions into account. These three volume integrals can be expressed as follows:

V₁₁ = 2 ⋅ ∫₀^(r 1)Δ n(r) ⋅ r ⋅ 𝕕r ≈ r₁² × Δ n₁ V₁₂ = 2 ⋅ ∫_(r 1)^(r 2)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₂² − r₁²) × Δ n₂ V₁₃ = 2 ⋅ ∫_(r 2)^(r 3)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₃² − r₂²) × Δ n₃.

Table 12 (below) shows nine examples of fiber profiles according to preferred fiber embodiments in comparison with three SSMF fiber profiles and one fiber profile corresponding to the G.657A and G.657B recommendations (noted as “BIF” for Bend Insensitive Fiber), as well as 13 comparative examples. Draka Comteq markets bend-insensitive optical fibers having excellent resistance to bending losses under the trade name BendBright^(XS)®. The values in the tables correspond to the set profiles for each fiber.

All profiles were also designed to ensure a Multi-Path Interference (MPI) level lower than −30 dB, which ensures full compatibility with any properly installed system networks, including Access Network and Fiber-to-the-Home. MPI is defined in W. Zheng et al., “Measurement and System Impact of Multipath Interference From Dispersion Compensating Fiber Modules,” IEEE Transactions on Instrumentation and Measurement (2004, 53, pp. 15-23) and its particular measurement considerations detailed in S. Ramachandran et al., “Measurement of Multipath Interference in the Coherent Crosstalk Regime,” IEEE Photonics Technology Letters (2003, 15, pp. 1171-1173).

The first column of Table 12 assigns a reference to each example (i.e., “Ex” for examples according to the disclosure and “C.Ex” for comparative examples); the next three columns give the values of the radii of the core (11), the intermediate cladding (12), and the depressed trench (13), respectively. The next three columns give the corresponding values of the refractive index differences with the external optical cladding (14). The refractive index values are measured at a wavelength of 633 nanometers. Table 12 also shows the surface integral and volume integral values of the core (11), the intermediate cladding (12) and the depressed trench (13), as defined above.

TABLE 12 V₀₁ V₀₂ V₀₃ V₁₁ V₁₂ V₁₃ r₁ r₂ r₃ Dn₁ Dn₂ Dn₃ (μm) (μm) (μm) (μm²) (μm²) (μm²) (μm) (μm) (μm) [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] [10⁻³] BIF 3.93 9.38 14.72 5.26 0.13 −5.01 20.7 0.7 −26.8 81.1 9.4 −645 SSMF1 4.35 13.92 5.00 −0.20 21.8 −1.9 0.0 94.6 −35.0 0 SSMF2 4.51 13.92 5.00 −0.20 22.5 −1.9 0.0 101.5 −34.7 0 SSMF3 4.55 13.92 5.24 −0.20 23.8 −1.9 0.0 108.4 −34.6 0 C. Ex 1 3.82 9.01 13.55 5.67 0.57 −9.63 21.7 2.9 −43.7 82.8 37.7 −986 C. Ex 2 3.96 8.61 13.86 5.58 0.31 −7.87 22.1 1.4 −41.3 87.6 17.9 −928 C. Ex 3 3.92 8.78 13.84 5.55 0.32 −8.75 21.7 1.5 −44.3 85.2 19.7 −1002 C. Ex 4 3.88 9.09 14.35 5.62 0.34 −7.84 21.8 1.8 −41.2 84.5 23.1 −965 C. Ex 5 3.93 9.30 14.48 5.30 0.51 −7.76 20.8 2.7 −40.1 81.7 36.0 −955 C. Ex 6 3.93 9.28 14.47 5.31 0.53 −7.51 20.9 2.8 −39.0 82.0 37.5 −926 C. Ex 7 3.93 8.50 15.00 5.48 0.50 −5.00 21.5 2.3 −32.5 84.6 28.4 −764 C. Ex 8 3.93 9.25 13.65 5.37 0.50 −9.90 21.1 2.7 −43.5 83.0 35.1 −997 C. Ex 9 3.93 8.50 15.50 5.33 0.51 −5.00 21.0 2.3 −35.0 82.4 28.8 −840 C. Ex 3.93 9.27 13.65 5.31 0.52 −9.80 20.9 2.8 −42.9 82.1 36.9 −983 10 C. Ex 3.94 9.25 13.54 5.30 0.56 −9.87 20.9 3.0 −42.3 82.3 39.2 −964 11 C. Ex 3.95 9.29 13.91 5.30 0.50 −8.93 20.9 2.7 −41.2 82.6 35.4 −957 12 C. Ex 3.93 8.50 15.50 5.32 0.57 −5.00 20.9 2.6 −35.0 82.1 32.2 −840 13 Ex 1 3.90 9.23 14.34 4.94 0.35 −7.15 19.3 1.9 −36.5 75.1 24.5 −861 Ex 2 3.91 9.23 14.34 5.14 0.10 −7.15 20.1 0.5 −36.5 78.6 7.0 −861 Ex 3 3.91 9.23 14.81 5.14 0.10 −7.15 20.1 0.5 −39.9 78.6 7.0 −959 Ex 4 3.91 9.23 14.34 5.29 −0.06 −7.15 20.7 −0.3 −36.5 80.9 −4.2 −861 Ex 5 3.91 9.23 14.81 5.29 −0.06 −7.15 20.7 −0.3 −39.9 80.9 −4.2 −959 Ex 6 3.93 9.26 13.53 5.34 0.51 −9.74 21.0 2.7 −41.6 82.3 36.0 −949 Ex 7 3.93 9.25 13.53 5.31 0.50 −9.93 20.8 2.7 −42.5 81.9 35.3 −967 Ex 8 3.94 8.50 15.00 5.43 0.50 −5.00 21.4 2.3 −32.5 84.3 28.6 −764 Ex 9 3.94 9.26 13.50 5.33 0.51 −9.88 21.0 2.7 −41.9 82.8 35.5 −954

The disclosed fiber (10) according to the embodiment depicted in FIGS. 23 and 24 is a step-index fiber comprising a central core (11), an intermediate cladding (12), and a depressed trench (13). It is noted from Table 12 that the central core (11) has a radius r₁ between 3.8 microns and 4.35 microns and preferably between 3.8 microns and 4.05 μm, i.e., narrower than the core of an SSMF fiber. The fiber (10) has an index difference Δn₁ (21) with the external optical cladding (14) between 4.9×10⁻³ and 5.7×10⁻³ (i.e., in the order of or greater than an SSMF fiber). The surface integral of the core V₀₁ is between 19.0×10⁻³ microns and 23.0×10⁻³ μm, and the volume integral of the core V₁₁ is between 75×10⁻³ μm² and 91×10⁻³ μm².

It is also noted from Table 12 that the disclosed fiber has a depressed trench (13). The depressed trench (13) has a large volume and makes it possible to greatly limit the bending losses. Table 12 thus shows that the depressed trench (13) has a radius r₃ between 13.5 microns and 16 microns and an index difference Δn₃ (23) with the external optical cladding (14) between −10.0×10⁻³ and −5.0×10⁻³. Table 12 also shows that the surface integral of the depressed trench V₀₃, as defined above, is between −55.0×10⁻³ microns and −30.0×10⁻³ μm, and the volume integral of the depressed trench V₁₃, as defined above, is between −1200×10⁻³ μm² and −750×10⁻³ μm².

According to a preferred embodiment, the radius of the depressed cladding r₃ can be limited to 15 microns to further reduce the cost of production of the fiber and all fibers according to the examples comply herewith. In fact, the depressed trench (13) can be produced by plasma chemical vapor deposition (PCVD) making it possible to incorporate a large quantity of fluorine in the silica to form deeply depressed claddings. The part of the fiber (10) corresponding to the tube and to the PCVD deposition is, however, the most expensive; it is therefore sought to limit this part as much as possible. It is also possible to envisage producing the depressed trench (13) by incorporation of micro-holes or micro-bubbles rather than by fluorine doping. Fluorine doping, however, remains easier to control for industrial production than the incorporation of micro-bubbles.

A depressed trench (13) corresponding to the surface and volume criteria defined above makes it possible to achieve a good compromise between greatly reduced bending losses relative to the existing fibers and a sufficiently consistent leakage regime of the LP11 mode at a wavelength of 1260 nanometers.

It is also noted from Table 12 that a preferred embodiment of the fiber has an intermediate cladding (12) between the central core (11) and the depressed trench (13). This intermediate cladding (12) makes it possible to limit the effects of the depressed trench (13) on the propagation of the optical signal in the core. Table 12 shows that the intermediate cladding (12) has a radius r₂ between 8.5 microns and 9.7 microns and an index difference Δn₂ (22) with the optical cladding between −0.1×10⁻³ and 0.6×10⁻³. Table 12 shows that the surface integral of the intermediate cladding V₀₂, as defined above, is between −0.5×10⁻³ microns and 3.0×10⁻³ microns. The volume integral of the intermediate cladding V₁₂, as defined above, is between −6×10⁻³ μm² and 40×10⁻³ μm².

The central core (11) of the disclosed fiber (10) is optimized, in combination with the intermediate cladding (12), to guarantee parameters of optical transmission in the fiber in conformity with the G.652 and G657A recommendations, particularly in terms of mode field diameter and chromatic dispersion. This also helps ensure compatibility with fibers of other optical systems.

Table 13 (below) shows the optical transmission characteristics for exemplary fibers. The first column repeats the references of Table 12. The following columns provide, for each fiber profile, the mode field diameter (MFD) values for wavelengths of 1310 nanometers and 1550 nanometers, zero dispersion wavelength (ZDW) and zero dispersion slope (ZDS).

TABLE 13 MFD1310 MFD1550 ZDW ZDS (μm) (μm) (nm) ps/(nm² · km) BIF 8.80 9.90 1320 0.0878 SSMF1 9.14 10.31 1314 0.0855 SSMF2 9.27 10.39 1309 0.0871 SSMF3 9.18 10.25 1306 0.088 C. Ex 1 8.67 9.68 1317 0.0908 C. Ex 2 8.65 9.59 1310 0.0917 C. Ex 3 8.66 9.62 1312 0.0914 C. Ex 4 8.64 9.65 1317 0.0897 C. Ex 5 8.95 10.01 1317 0.0905 C. Ex 6 8.96 10.02 1317 0.0905 C. Ex 7 8.80 9.81 1314 0.0906 C. Ex 8 8.89 9.91 1315 0.0913 C. Ex 9 8.88 9.91 1314 0.0909 C. Ex 10 8.94 9.97 1315 0.0914 C. Ex 11 8.97 10.00 1314 0.0917 C. Ex 12 8.95 9.99 1315 0.0911 C. Ex 13 8.92 9.95 1314 0.0911 Ex 1 9.00 10.10 1318 0.0906 Ex 2 8.75 9.81 1318 0.0895 Ex 3 8.75 9.81 1318 0.0895 Ex 4 8.60 9.64 1318 0.0888 Ex 5 8.60 9.64 1318 0.0888 Ex 6 8.91 9.94 1315 0.0913 Ex 7 8.92 9.95 1315 0.0914 Ex 8 8.83 9.84 1313 0.0908 Ex 9 8.93 9.95 1314 0.0915

It is noted from Table 13 that the disclosed fiber (10) is compatible with fibers corresponding to the criteria of the G.652 recommendation. In particular, the fiber disclosed herein has a mode field diameter MFD in the standardized range of values from 8.6 microns to 9.5 microns at 1310 nanometers, a zero dispersion wavelength between 1300 nanometers and 1324 nanometers, and a zero dispersion slope of less than 0.092 ps/(nm²·km). Each of these values is in accordance with the recommendation G.652.

On the other hand, as shown by Table 14 (below), the fiber has an effective cut-off wavelength λ_(ceff) (or standard fiber cut-off, third column of Table 14) greater than 1300 nanometers, or even greater than 1350 nanometers. As discussed above, the effective cut-off wavelength is measured as being the wavelength at which the optical signal is no longer single mode after propagation over two meters of fiber, as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-44 standard. This increased effective cut-off wavelength value leads to a cable cut-off wavelength value λ_(cc) (or standard cable cut-off fifth column of Table 14) between 1200 nanometers and 1260 nanometers. The cable cut-off wavelength is measured as the wavelength at which the optical signal is no longer single mode after propagation over 22 meters of fiber, as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard. The optical signal is single mode when the attenuation of the LP11 mode is greater than or equal to 19.3 dB. The G.652 and G.657 recommendations both impose a maximum value of 1260 nanometers for the cable cut-off wavelength.

One purpose of the developments disclosed herein is to produce fibers that can be used on all of the transmission bandwidths exploited by optical systems, i.e., fibers that can be used in single mode propagation from the original bandwidth (OB) which extends from 1260 nanometers to 1360 nanometers, and as far as the ultra-long (UL) bandwidth beyond 1625 nanometers. A low effective cut-off wavelength makes it possible to guarantee the possibility of using the fiber over all of the available bandwidths.

The simulations of Table 14 (below), however, show that the directly higher order LP11 mode is propagated according to a leaky mode from a wavelength of 1260 nanometers. The fiber disclosed herein can, therefore, be used in single mode transmission over the original bandwidth (OB: 1260 nanometers to 1360 nanometers).

Table 14 (below) shows several cut-off wavelength values for the disclosed fibers. The first column of Table 14 repeats the references of Table 12.

The column “Theoretical Fiber Cutoff” provides a theoretical cut-off wavelength value, which corresponds to the transition wavelength between a guided propagation of the LP11 mode and a propagation in leaky mode of this LP11 mode. For working wavelengths beyond this effective cut-off wavelength, the LP11 mode is propagated in leaky mode.

The column “Standard Fiber Cutoff” corresponds to the effective cut-off wavelength λ_(ceff) as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard.

The column “5-m Fiber Cutoff” corresponds to the cut-off wavelength measured as the wavelength over which the optical signal is no longer multi mode after propagation over five meters of fiber. This value therefore corresponds to the effective cut-off wavelength measured after propagation over five meters of fiber instead of two meters of fiber.

The column “Standard Cable Cutoff” corresponds to the cable cut-off wavelength λ_(cc) as defined by Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard. According to the recommendation of Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard, the cable cut-off wavelength λ_(cc) is determined by positioning the fiber into two 40 millimeters radius loops and by arranging the remainder of the fiber (i.e., 21.5 meters of fiber) on a mandrel with a radius of 140 millimeters. This cut-off should be 1260 nanometers or less.

The column “Straight Cable Cutoff” corresponds to the cable cut-off wavelength by positioning the fiber into two loops each having a 40-millimeter radius, and by arranging the remainder of the fiber (i.e., 21.5 meters of fiber) virtually straight. This cut-off should be 1260 nanometers or less. Comparative Examples 9, 10 and 12 comply with this requirement but are slightly too high regarding standard cable cut-off.

The column “LP11 LL @1260 after 22 m” indicates the leakage losses of the LP11 mode after propagation over 22 meters of virtually straight fiber.

The column “Length—19.3 dB LP11 LL @1260 nanometers” indicates the length of fiber required to achieve leakage losses of the LP11 mode equal to 19.3 dB with the fiber being kept virtually straight. This indicates at which distance the fiber, arranged virtually straight, is single mode within the meaning of the G.652 and G.657 recommendations.

TABLE 14 Length- Straight LP11 LL 19.3 dB Fiber Cutoff Std Fiber 5-m Fiber Std Cable Cable @1260 nm LP11 LL (theory) Cutoff Cutoff Cutoff Cutoff after 22 m @1260 nm (nm) (nm) (nm) (nm) (nm) (dB) (m) BIF 1197 1270 1234 1196 1208 180 2 SSMF1 1287 1226 1226 1151 1151 2 212 SSMF2 1334 1267 1267 1188 1188 0 >1000 SSMF3 1381 1311 1311 1231 1231 0 >1000 C. Ex 1 1250 1379 1321 1271 1268 10 41 C. Ex 2 1243 1383 1323 1271 1266 16 27 C. Ex 3 1232 1397 1333 1271 1265 16 26 C. Ex 4 1239 1392 1331 1272 1267 15 28 C. Ex 5 1242 1382 1322 1268 1264 18 24 C. Ex 6 1247 1376 1319 1267 1266 15 28 C. Ex 7 1249 1351 1302 1259 1262 18 23 C. Ex 8 1246 1378 1319 1268 1264 17 25 C. Ex 9 1235 1373 1317 1264 1260 18 24 C. Ex 1243 1371 1313 1263 1260 22 20 10 C. Ex 1248 1367 1310 1263 1263 17 25 11 C. Ex 1244 1371 1314 1264 1260 20 21 12 C. Ex 1240 1375 1319 1267 1263 17 24 13 Ex 1 1175 1316 1255 1204 1201 88 5 Ex 2 1171 1316 1246 1205 1198 83 5 Ex 3 1171 1366 1271 1225 1205 44 10 Ex 4 1171 1316 1244 1207 1195 75 6 Ex 5 1171 1366 1269 1226 1200 40 11 Ex 9 1243 1360 1304 1257 1258 26 16 Ex 7 1238 1362 1305 1256 1255 24 17 Ex 8 1247 1350 1300 1257 1260 22 19 Ex 9 1245 1362 1306 1259 1259 24 18

It is noted from Table 14 that the standard effective cut-off wavelength α_(ceff), i.e., as measured according to the recommendations of Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-1-44 standard, is greater than 1300 nanometers. Similarly, it is noted from Table 14 that the standard cable cut-off wavelength λ_(cc), i.e., as measured according to the recommendations of Subcommittee 86A of the International Electrotechnical Commission in IEC 60793-44 standard, is between 1200 nanometers and 1260 nanometers (i.e., complying with the limit of 1260 nanometers imposed by the G.652 and G.657 recommendations).

It is noted from Table 14 that the LP11 mode is highly attenuated from a wavelength of 1260 nanometers. In fact, the “theoretical” fiber cut-off wavelength is less than or equal to 1250 nanometers. Thus, the higher order LP11 mode is propagated in a leaky mode regime in the original bandwidth, and only the fundamental mode remains guided in the disclosed fiber as from a wavelength of 1260 nanometers.

Similarly, it is noted from Table 14 that the fiber cut-off wavelength is significantly reduced after only 5 meters of propagation in the fiber. Thus, the cut-off wavelength, measured as the wavelength at which the optical signal is no longer single mode after propagation over five meters of fiber, is between 1240 nanometers and 1310 nanometers for the disclosed fiber.

Moreover, Table 14 clearly shows that the LP11 mode is already well attenuated after 22 meters of propagation. It is noted in particular that the attenuation of the LP11 mode in the disclosed fiber (10) is greater than the attenuation of the LP11 mode in an SSMF fiber when the fiber is arranged virtually straight. In fact, in an SSMF fiber, it is the bends that make it possible to highly attenuate the LP11 mode. Thus, the fiber has an attenuation of the LP11 mode greater than 5 dB after 22 meters of propagation in straight fiber at a wavelength of 1260 nanometers.

Moreover, Table 14 also shows that the attenuation of at least 19.3 dB of the LP11 mode is achieved relatively rapidly, after less than 22 meters, in accordance with cable cut-off imposed by the recommendation. Moreover, the increase in the effective cut-off wavelength makes it possible to increase the value of the MAC as defined above and consequently to reduce the bending losses.

Table 15 (below) reports bending loss values for preferred embodiments of fibers as disclosed herein. The first column of Table 15 repeats the references of Table 12. The next four columns show bending loss values PPC for respective radii of curvature of 15 millimeters, 10 millimeters, 7.5 millimeters and 5 millimeters at a wavelength of 1550 nanometers. The next four columns give bending loss values PPC for respective radii of curvature of 15 millimeters, 10 millimeters, 7.5 millimeters and 5 millimeters at a wavelength of 1625 nanometers.

The last column has a factor of merit (FOM) representing the order of magnitude of the improvement in the bending losses by the disclosed fibers relative to the limits imposed by the G.657B recommendation. The FOM of Table 15 is thus defined as an average of the ratios between the upper limits imposed by the G.657B standard and the bending losses in the disclosed fibers for each radius of curvature measured. All examples present a FOM lower than or equal to 1, thus meaning they all comply with the G.657B bend losses recommendations.

Table 15 reports on the first line the bending loss limit values imposed by the G.657B recommendation for each radius of curvature and for the wavelengths of 1550 nanometers and 1625 nanometers.

TABLE 15 R = 15 mm R = 10 mm R = 7.5 mm R = 5 mm R = 15 mm R = 10 mm R = 7.5 mm R = 5 mm PPC @1550 nm (dB/turn) PPC @1625 nm (dB/turn) FOM G657B   3E−03   1E−01   5E−01   1E−02   2E−01   1E+00 1.00 BIF 1.3E−03 2.9E−02 1.0E−01 3.3E−01 7.0E−03 8.4E−02 2.3E−01 6.3E−01 0.70 SSMF1 1.5E−02 6.0E−01 3.4E+00 1.7E+01 7.5E−02 1.7E+00 6.9E+00 2.7E+01 8.44 SSMF2 6.3E−03 3.6E−01 2.4E+00 1.4E+01 3.4E−02 1.0E+00 5.0E+00 2.3E+01 5.21 SSMF3 9.6E−04 1.1E−01 1.0E+00 8.9E+00 6.5E−03 3.6E−01 2.5E+00 1.4E+01 2.45 C. Ex 1 4.9E−05 2.9E−03 1.6E−02 7.1E−02 3.9E−04 1.1E−02 4.2E−02 1.3E−01 0.05 C. Ex 2 5.4E−05 2.9E−03 1.6E−02 6.5E−02 4.3E−04 1.1E−02 4.1E−02 1.3E−01 0.05 C. Ex 3 6.6E−05 3.0E−03 1.5E−02 5.6E−02 5.0E−04 1.1E−02 3.8E−02 1.1E−01 0.05 C. Ex 4 6.2E−05 3.1E−03 1.5E−02 6.3E−02 4.7E−04 1.1E−02 3.9E−02 1.2E−01 0.06 C. Ex 5 2.2E−04 6.9E−03 2.7E−02 1.0E−01 1.3E−03 2.1E−02 6.4E−02 1.8E−01 0.13 C. Ex 6 2.1E−04 7.1E−03 2.9E−02 1.1E−01 1.3E−03 2.2E−02 6.9E−02 2.0E−01 0.13 C. Ex 7 1.4E−04 6.5E−03 3.1E−02 1.3E−01 1.0E−03 2.2E−02 7.7E−02 2.4E−01 0.11 C. Ex 8 1.4E−04 5.4E−03 2.4E−02 9.0E−02 9.2E−04 1.8E−02 5.8E−02 1.7E−01 0.09 C. Ex 9 2.3E−04 7.3E−03 2.8E−02 1.0E−01 1.4E−03 2.3E−02 6.8E−02 2.0E−01 0.14 C. Ex 2.0E−04 6.8E−03 2.9E−02 1.0E−01 1.2E−03 2.2E−02 6.8E−02 2.0E−01 0.12 10 C. Ex 2.0E−04 7.1E−03 3.0E−02 1.1E−01 1.2E−03 2.3E−02 7.1E−02 2.1E−01 0.12 11 C. Ex 2.0E−04 7.0E−03 2.9E−02 1.0E−01 1.3E−03 2.2E−02 6.8E−02 2.0E−01 0.13 12 C. Ex 2.3E−04 7.4E−03 2.9E−02 1.1E−01 1.4E−03 2.3E−02 7.0E−02 2.1E−01 0.14 13 Ex 1 2.3E−03 2.8E−02 8.0E−02 1.4E−01 1.0E−02 7.5E−02 1.7E−01 2.5E−01 1.00 Ex 2 1.2E−03 1.9E−02 5.0E−02 1.0E−01 6.5E−03 5.4E−02 1.3E−01 2.1E−01 0.65 Ex 3 8.5E−04 1.2E−02 3.6E−02 6.7E−02 4.5E−03 3.7E−02 8.4E−02 1.4E−01 0.45 Ex 4 7.1E−04 1.3E−02 4.3E−02 8.7E−02 4.1E−03 4.2E−02 1.0E−01 1.8E−01 0.41 Ex 5 4.9E−04 8.7E−03 2.8E−02 5.6E−02 2.8E−03 2.8E−02 6.7E−02 1.2E−01 0.28 Ex 6 2.0E−04 7.1E−03 3.1E−02 1.1E−01 1.2E−03 2.3E−02 7.2E−02 2.1E−01 0.12 Ex 7 2.2E−04 7.4E−03 3.1E−02 1.1E−01 1.4E−03 2.4E−02 7.2E−02 2.1E−01 0.14 Ex 8 1.7E−04 7.4E−03 3.4E−02 1.3E−01 1.2E−03 2.4E−02 8.2E−02 2.5E−01 0.12 Ex 9 1.9E−04 7.0E−03 3.0E−02 1.1E−01 1.2E−03 2.3E−02 7.2E−02 2.1E−01 0.12

It is noted from Table 15 that the bending losses of the disclosed fibers are clearly less than the limits imposed by the G.657B standard, though for Example 1 the bending loss at 1625 nanometers at a curvature of 15 millimeters is the same as the recommendation.

Thus, the fiber disclosed (above) has, for a wavelength of 1550 nanometers, bending losses less than 3×10⁻³ dB/turn, preferably less than 0.25×10⁻³ dB/turn for a radius of curvature of 15 millimeters, as compared to a limit of 3×10⁻³ dB/turn imposed by the G.657B recommendation. The fiber further has bending losses less than or equal 3×10⁻², preferably less than or equal to 7.5×10⁻³ dB/turn for a radius of curvature of 10 millimeters, as compared against a limit of 0.1 dB/turn imposed by the G.657B recommendation. The bending losses are less than or equal to 0.05 dB/turn for a radius of curvature of 7.5 millimeters, as against a limit of 0.5 dB/turn imposed by the G.657B recommendation, and bending losses less than 0.15 dB/turn, preferably less than or equal to 0.10 dB/turn for a radius of curvature of millimeters.

Similarly, the disclosed fiber exhibits, for a wavelength of 1625 nanometers, bending losses less than 10⁻² dB/turn, preferably less than 1.5×10⁻³ dB/turn for a radius of curvature of 15 millimeters, as compared to a limit of 10⁻² dB/turn imposed by the G.657B recommendation. The bending losses are less than or equal to 0.1 dB/turn, preferably less than or equal to 25×10⁻³ dB/turn for a radius of curvature of millimeters, as compared to a limit of 0.2 dB/turn imposed by the G.657B recommendation. The fiber exhibits bending losses less than or equal to 0.15 dB/turn, preferably less than or equal to 0.08 dB/turn for a radius of curvature of 7.5 millimeters, as against a limit of 1 dB/turn imposed by the G.657B recommendation, and bending losses less than 0.25 dB/turn for a radius of curvature of 5 millimeters.

The fibers disclosed herein are well suited to a use in optical systems installed in the subscriber's home, of FTTH type, in which the fiber is subjected to significant bend stresses due to the miniaturization of the optical box or holding the fiber in place with staples. The fiber can be placed in particularly compact optical boxes. In fact, the optical fiber may be arranged with a radius of curvature of less than 15 millimeters, for example, a radius of curvature about 5 millimeters. The fiber remains compatible with the fibers of existing systems, in particular in terms of mode field diameter for good fiber-to-fiber coupling. The increase in the cut-off wavelength is not detrimental due to a significant attenuation of the LP11 mode from a wavelength of 1260 nanometers.

As noted, the optical fiber according to the present invention includes one or more coating layers (e.g., a primary coating and a secondary coating). At least one of the coating layers—typically the secondary coating—may be colored and/or possess other markings to help identify individual fibers. Alternatively, a tertiary ink layer may surround the primary and secondary coatings.

The optical fiber according to the present invention may be deployed in various structures, such as those exemplary structures disclosed hereinafter.

For example, one or more of the present optical fibers may be enclosed within a buffer tube. For instance, optical fiber may be deployed in either a single fiber loose buffer tube or a multi-fiber loose buffer tube. With respect to the latter, multiple optical fibers may be bundled or stranded within a buffer tube or other structure. In this regard, within a multi-fiber loose buffer tube, fiber sub-bundles may be separated with binders (e.g., each fiber sub-bundle is enveloped in a binder). Moreover, fan-out tubing may be installed at the termination of such loose buffer tubes to directly terminate loose buffered optical fibers with field-installed connectors.

In other embodiments, the buffer tube may tightly surround the outermost optical fiber coating (i.e., tight buffered fiber) or otherwise surround the outermost optical fiber coating or ink layer to provide an exemplary radial clearance of between about 50 and 100 microns (i.e., a semi-tight buffered fiber).

With respect to the former tight buffered fiber, the buffering may be formed by coating the optical fiber with a curable composition (e.g., a UV-curable material) or a thermoplastic material. The outer diameter of tight buffer tubes, regardless of whether the buffer tube is formed from a curable or non-curable material, is typically less than about 1,000 microns (e.g., either about 500 microns or about 900 microns).

With respect to the latter semi-tight buffered fiber, a lubricant may be included between the optical fiber and the buffer tube (e.g., to provide a gliding layer).

As will be known by those having ordinary skill in the art, an exemplary buffer tube enclosing optical fibers as disclosed herein may be formed of polyolefins (e.g., polyethylene or polypropylene), including fluorinated polyolefins, polyesters (e.g., polybutylene terephthalate), polyamides (e.g., nylon), as well as other polymeric materials and blends. In general, a buffer tube may be formed of one or more layers. The layers may be homogeneous or include mixtures or blends of various materials within each layer.

In this context, the buffer tube may be extruded (e.g., an extruded polymeric material) or pultruded (e.g., a pultruded, fiber-reinforced plastic). By way of example, the buffer tube may include a material to provide high temperature and chemical resistance (e.g., an aromatic material or polysulfone material).

Although buffer tubes typically have a circular cross section, buffer tubes alternatively may have an irregular or non-circular shape (e.g., an oval or a trapezoidal cross-section).

Alternatively, one or more of the present optical fibers may simply be surrounded by an outer protective sheath or encapsulated within a sealed metal tube. In either structure, no intermediate buffer tube is necessarily required.

Multiple optical fibers as disclosed herein may be sandwiched, encapsulated, and/or edge bonded to form an optical fiber ribbon. Optical fiber ribbons can be divisible into subunits (e.g., a twelve-fiber ribbon that is splittable into six-fiber subunits). Moreover, a plurality of such optical fiber ribbons may be aggregated to form a ribbon stack, which can have various sizes and shapes.

For example, it is possible to form a rectangular ribbon stack or a ribbon stack in which the uppermost and lowermost optical fiber ribbons have fewer optical fibers than those toward the center of the stack. This construction may be useful to increase the density of optical elements (e.g., optical fibers) within the buffer tube and/or cable.

In general, it is desirable to increase the filling of transmission elements in buffer tubes or cables, subject to other constraints (e.g., cable or mid-span attenuation). The optical elements themselves may be designed for increased packing density. For example, the optical fiber may possess modified properties, such as improved refractive-index profile, core or cladding dimensions, or primary coating thickness and/or modulus, to improve microbending and macrobending characteristics.

By way of example, a rectangular ribbon stack may be formed with or without a central twist (i.e., a “primary twist”). Those having ordinary skill in the art will appreciate that a ribbon stack is typically manufactured with rotational twist to allow the tube or cable to bend without placing excessive mechanical stress on the optical fibers during winding, installation, and use. In a structural variation, a twisted (or untwisted) rectangular ribbon stack may be further formed into a coil-like configuration (e.g., a helix) or a wave-like configuration (e.g., a sinusoid). In other words, the ribbon stack may possess regular “secondary” deformations.

As will be known to those having ordinary skill in the art, such optical fiber ribbons may be positioned within a buffer tube or other surrounding structure, such as a buffer-tube-free cable. Subject to certain restraints (e.g., attenuation) it is desirable to increase the density of elements such as optical fibers or optical fiber ribbons within buffer tubes and/or optical fiber cables.

A plurality of buffer tubes containing optical fibers (e.g., loose or ribbonized fibers) may be positioned externally adjacent to and stranded around a central strength member. This stranding can be accomplished in one direction, helically, known as “S” or “Z” stranding, or Reverse Oscillated Lay stranding, known as “S-Z” stranding. Stranding about the central strength member reduces optical fiber strain when cable strain occurs during installation and use.

Those having ordinary skill in the art will understand the benefit of minimizing fiber strain for both tensile cable strain and longitudinal compressive cable strain during installation or operating conditions.

With respect to tensile cable strain, which may occur during installation, the cable will become longer while the optical fibers can migrate closer to the cable's neutral axis to reduce, if not eliminate, the strain being translated to the optical fibers. With respect to longitudinal compressive strain, which may occur at low operating temperatures due to shrinkage of the cable components, the optical fibers will migrate farther away from the cable's neutral axis to reduce, if not eliminate, the compressive strain being translated to the optical fibers.

In a variation, two or more substantially concentric layers of buffer tubes may be positioned around a central strength member. In a further variation, multiple stranding elements (e.g., multiple buffer tubes stranded around a strength member) may themselves be stranded around each other or around a primary central strength member.

Alternatively, a plurality of buffer tubes containing optical fibers (e.g., loose or ribbonized fibers) may be simply placed externally adjacent to the central strength member (i.e., the buffer tubes are not intentionally stranded or arranged around the central strength member in a particular manner and run substantially parallel to the central strength member).

Alternatively still, the present optical fibers may be positioned within a central buffer tube (i.e., the central buffer tube cable has a central buffer tube rather than a central strength member). Such a central buffer tube cable may position strength members elsewhere. For instance, metallic or non-metallic (e.g., GRP) strength members may be positioned within the cable sheath itself, and/or one or more layers of high-strength yarns (e.g., aramid or non-aramid yarns) may be positioned parallel to or wrapped (e.g., contrahelically) around the central buffer tube (i.e., within the cable's interior space). Likewise, strength members can be included within the buffer tube's casing.

In other embodiments, the optical fibers may be placed within a slotted core cable. In a slotted core cable, optical fibers, individually or as a fiber ribbon, may be placed within pre-shaped helical grooves (i.e., channels) on the surface of a central strength member, thereby forming a slotted core unit. The slotted core unit may be enclosed by a buffer tube. One or more of such slotted core units may be placed within a slotted core cable. For example, a plurality of slotted core units may be helically stranded around a central strength member.

Alternatively, the optical fibers may also be stranded in a maxitube cable design, whereby the optical fibers are stranded around themselves within a large multi-fiber loose buffer tube rather than around a central strength member. In other words, the large multi-fiber loose buffer tube is centrally positioned within the maxitube cable. For example, such maxitube cables may be deployed in optical ground wires (OPGW).

In another cabling embodiment, multiple buffer tubes may be stranded around themselves without the presence of a central member. These stranded buffer tubes may be surrounded by a protective tube. The protective tube may serve as the outer casing of the fiber optic cable or may be further surrounded by an outer sheath. The protective tube may tightly or loosely surround the stranded buffer tubes.

As will be known to those having ordinary skill in the art, additional elements may be included within a cable core. For example, copper cables or other active, transmission elements may be stranded or otherwise bundled within the cable sheath. Passive elements may also be placed within the cable core, such as between the interior walls of the buffer tubes and the enclosed optical fibers. Alternatively and by way of example, passive elements may be placed outside the buffer tubes between the respective exterior walls of the buffer tubes and the interior wall of the cable jacket, or, within the interior space of a buffer-tube-free cable.

For example, yarns, nonwovens, fabrics (e.g., tapes), foams, or other materials containing water-swellable material and/or coated with water-swellable materials (e.g., including super absorbent polymers (SAPs), such as SAP powder) may be employed to provide water blocking and/or to couple the optical fibers to the surrounding buffer tube and/or cable jacketing (e.g., via adhesion, friction, and/or compression). Exemplary water-swellable elements are disclosed in commonly assigned U.S. Patent Application Publication No. US 2007/0019915 A1 and its related U.S. patent application Ser. No. 11/424,112, now U.S. Pat. No. 7,515,795, for a Water-Swellable Tape, Adhesive-Backed for Coupling When Used Inside a Buffer Tube (Overton et al.), each of which is hereby incorporated by reference in its entirety.

Moreover, an adhesive (e.g., a hot-melt adhesive or curable adhesive, such as a silicone acrylate cross-linked by exposure to actinic radiation) may be provided on one or more passive elements (e.g., water-swellable material) to bond the elements to the buffer tube. An adhesive material may also be used to bond the water-swellable element to optical fibers within the buffer tube. Exemplary arrangements of such elements are disclosed in commonly assigned U.S. Patent Application Publication No. US 2008/0145010 A1, now U.S. Pat. No. 7,599,589, for a Gel-Free Buffer Tube with Adhesively Coupled Optical Element (Overton et al.), which is hereby incorporated by reference in its entirety.

The buffer tubes (or buffer-tube-free cables) may also contain a thixotropic composition (e.g., grease or grease-like gels) between the optical fibers and the interior walls of the buffer tubes. For example, filling the free space inside a buffer tube with water-blocking, petroleum-based filling grease helps to block the ingress of water. Further, the thixotropic filling grease mechanically (i.e., viscously) couples the optical fibers to the surrounding buffer tube.

Such thixotropic filling greases are relatively heavy and messy, thereby hindering connection and splicing operations. Thus, the present optical fibers may be deployed in dry cable structures (i.e., grease-free buffer tubes).

Exemplary buffer tube structures that are free from thixotropic filling greases are disclosed in commonly assigned U.S. patent application Ser. No. 12/146,588, now published as U.S. Patent Application Publication No. 2009/0003785 A1, for a Coupling Composition for Optical Fiber Cables (Parris et al.), which is hereby incorporated by reference in its entirety. Such buffer tubes employ coupling compositions formed from a blend of high-molecular weight elastomeric polymers (e.g., about 35 weight percent or less) and oils (e.g., about 65 weight percent or more) that flow at low temperatures. Unlike thixotropic filling greases, the coupling composition (e.g., employed as a cohesive gel or foam) is typically dry and, therefore, less messy during splicing.

As will be understood by those having ordinary skill in the art, a cable enclosing optical fibers as disclosed herein may have a sheath formed from various materials in various designs. Cable sheathing may be formed from polymeric materials such as, for example, polyethylene, polypropylene, polyvinyl chloride (PVC), polyamides (e.g., nylon), polyester (e.g., PBT), fluorinated plastics (e.g., perfluorethylene propylene, polyvinyl fluoride, or polyvinylidene difluoride), and ethylene vinyl acetate. The sheath and/or buffer tube materials may also contain other additives, such as nucleating agents, flame-retardants, smoke-retardants, antioxidants, UV absorbers, and/or plasticizers.

The cable sheathing may be a single jacket formed from a dielectric material (e.g., non-conducting polymers), with or without supplemental structural components that may be used to improve the protection (e.g., from rodents) and strength provided by the cable sheath. For example, one or more layers of metallic (e.g., steel) tape along with one or more dielectric jackets may form the cable sheathing. Metallic or fiberglass reinforcing rods (e.g., GRP) may also be incorporated into the sheath. In addition, aramid, fiberglass, or polyester yarns may be employed under the various sheath materials (e.g., between the cable sheath and the cable core), and/or ripcords may be positioned, for example, within the cable sheath.

Similar to buffer tubes, optical fiber cable sheaths typically have a circular cross section, but cable sheaths alternatively may have an irregular or non-circular shape (e.g., an oval, trapezoidal, or flat cross-section).

By way of example, the optical fiber according to the present invention may be incorporated into single-fiber drop cables, such as those employed for Multiple Dwelling Unit (MDU) applications. In such deployments, the cable jacketing must exhibit crush resistance, abrasion resistance, puncture resistance, thermal stability, and fire resistance as required by building codes. An exemplary material for such cable jackets is thermally stable, flame-retardant polyurethane (PUR), which mechanically protects the optical fibers yet is sufficiently flexible to facilitate easy MDU installations. Alternatively, a flame-retardant polyolefin or polyvinyl chloride sheath may be used.

In general and as will be known to those having ordinary skill in the art, a strength member is typically in the form of a rod or braided/helically wound wires or fibers, though other configurations will be within the knowledge of those having ordinary skill in the art.

Optical fiber cables containing optical fibers as disclosed may be variously deployed, including as drop cables, distribution cables, feeder cables, trunk cables, and stub cables, each of which may have varying operational requirements (e.g., temperature range, crush resistance, UV resistance, and minimum bend radius).

Such optical fiber cables may be installed within ducts, microducts, plenums, or risers. By way of example, an optical fiber cable may be installed in an existing duct or microduct by pulling or blowing (e.g., using compressed air). An exemplary cable installation method is disclosed in commonly assigned U.S. Patent Application Publication No. 2007/0263960, now U.S. Pat. No. 7,574,095, for a Communication Cable Assembly and Installation Method (Lock et al.), and U.S. patent application Ser. No. 12/200,095, now U.S. Pat. No. 7,665,902, for a Modified Pre-Ferrulized Communication Cable Assembly and Installation Method (Griffioen et al.), each of which is incorporated by reference in its entirety.

As noted, buffer tubes containing optical fibers (e.g., loose or ribbonized fibers) may be stranded (e.g., around a central strength member). In such configurations, an optical fiber cable's protective outer sheath may have a textured outer surface that periodically varies lengthwise along the cable in a manner that replicates the stranded shape of the underlying buffer tubes. The textured profile of the protective outer sheath can improve the blowing performance of the optical fiber cable. The textured surface reduces the contact surface between the cable and the duct or microduct and increases the friction between the blowing medium (e.g., air) and the cable. The protective outer sheath may be made of a low coefficient-of-friction material, which can facilitate blown installation. Moreover, the protective outer sheath can be provided with a lubricant to further facilitate blown installation.

In general, to achieve satisfactory long-distance blowing performance (e.g., between about 3,000 to 5,000 feet or more), the outer cable diameter of an optical fiber cable should be no more than about seventy to eighty percent of the duct's or microduct's inner diameter.

Compressed air may also be used to install optical fibers according to the present invention in an air blown fiber system. In an air blown fiber system, a network of unfilled cables or microducts is installed prior to the installation of optical fibers. Optical fibers may subsequently be blown into the installed cables as necessary to support the network's varying requirements.

Moreover, the optical fiber cables may be directly buried in the ground or, as an aerial cable, suspended from a pole or pylori. An aerial cable may be self-supporting or secured or lashed to a support (e.g., messenger wire or another cable). Exemplary aerial fiber optic cables include overhead ground wires (OPGW), all-dielectric self-supporting cables (ADSS), all dielectric lash cables (AD-Lash), and figure-eight cables, each of which is well understood by those having ordinary skill in the art. (Figure-eight cables and other designs can be directly buried or installed into ducts, and may optionally include a toning element, such as a metallic wire, so that they can be found with a metal detector.

In addition, although the optical fibers may be further protected by an outer cable sheath, the optical fiber itself may be further reinforced so that the optical fiber may be included within a breakout cable, which allows for the individual routing of individual optical fibers.

To effectively employ the present optical fibers in a transmission system, connections are required at various points in the network. Optical fiber connections are typically made by fusion splicing, mechanical splicing, or mechanical connectors.

The mating ends of connectors can be installed to the fiber ends either in the field (e.g., at the network location) or in a factory prior to installation into the network. The ends of the connectors are mated in the field in order to connect the fibers together or connect the fibers to the passive or active components. For example, certain optical fiber cable assemblies (e.g., furcation assemblies) can separate and convey individual optical fibers from a multiple optical fiber cable to connectors in a protective manner.

The deployment of such optical fiber cables may include supplemental equipment. For instance, an amplifier may be included to improve optical signals. Dispersion compensating modules may be installed to reduce the effects of chromatic dispersion and polarization mode dispersion. Splice boxes, pedestals, and distribution frames, which may be protected by an enclosure, may likewise be included. Additional elements include, for example, remote terminal switches, optical network units, optical splitters, and central office switches.

A cable containing optical fibers according to the present invention may be deployed for use in a communication system (e.g., networking or telecommunications). A communication system may include fiber optic cable architecture such as fiber-to-the-node (FTTN), fiber-to-the-telecommunications enclosure (FTTE), fiber-to-the-curb (FTTC), fiber-to-the-building (FTTB), and fiber-to-the-home (FTTH), as well as long-haul or metro architecture. Moreover, an optical module or a storage box that includes a housing may receive a wound portion of the optical fiber disclosed herein. By way of example, the optical fiber may be wound with a bending radius of less than about 15 millimeters (e.g., 10 millimeters or less, such as about 5 millimeters) in the optical module or the storage box.

Moreover, optical fibers according to the present invention may be used in other applications, including, without limitation, fiber optic sensors or illumination applications (e.g., lighting).

In another aspect, the optical fibers according to the present invention may be enclosed by buffer tubes formed from a hardened polymer material (e.g., polysulfone).

Those having ordinary skill in the art will appreciate that hardened buffer tubes subject conventional optical fibers to excessive risk of microbending. In contrast and as noted, the present bend-insensitive optical fibers provide exceptional microbending resistance, and so can be satisfactory deployed in hardened buffer tubes.

By way of example, the hardened buffer tube may have an outer diameter between about one and two millimeters. An exemplary hardened buffer tube may possess an inner diameter of about 300 microns, thus forming a single-fiber, semi-tight buffer tube (e.g., a hardened buffer tube having an outer diameter of 1.0 millimeters and an inner diameter of about 300 microns).

In a particular embodiment, a bend-insensitive optical fiber according to the present invention may be enclosed by a hardened buffer tube formed from polysulfone, such as by extrusion or pultrusion. This kind of hardened buffer tube provides superior resistance to lateral stresses that could otherwise cause microbending or macrobending of the enclosed optical fiber. The hardened buffer tube is capable of withstanding high temperatures (e.g., 200° C.) and exposure to corrosive chemicals (e.g., gasoline). Similar to more complex structures, the present hardened buffer tube offers protection against lateral stresses, high temperatures, and corrosive chemicals yet is less expensive and simpler to manufacture.

This application incorporates entirely by reference the following commonly assigned patents, patent application publications, and patent applications: U.S. Pat. No. 5,574,816 for Polypropylene-Polyethylene Copolymer Buffer Tubes for Optical Fiber Cables and Method for Making the Same, and its related patent application Ser. No. 08/377,366; U.S. Pat. No. 5,717,805 for Stress Concentrations in an Optical Fiber Ribbon to Facilitate Separation of Ribbon Matrix Material; U.S. Pat. No. 5,761,362 for Polypropylene-Polyethylene Copolymer Buffer Tubes for Optical Fiber Cables and Method for Making the Same; U.S. Pat. No. 5,911,023 for Polyolefin Materials Suitable for Optical Fiber Cable Components; U.S. Pat. No. 5,982,968 for Stress Concentrations in an Optical Fiber Ribbon to Facilitate Separation of Ribbon Matrix Material; U.S. Pat. No. 6,035,087 for Optical Unit for Fiber Optic Cables; U.S. Pat. No. 6,066,397 for Polypropylene Filler Rods for Optical Fiber Communications Cables; U.S. Pat. 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In the specification and/or figures, typical embodiments of the invention have been disclosed. The present invention is not limited to such exemplary embodiments. The figures are schematic representations and so are not necessarily drawn to scale. Unless otherwise noted, specific terms have been used in a generic and descriptive sense and not for purposes of limitation. 

1. A bend-insensitive optical fiber, comprising: a single-mode glass fiber comprising (i) a central core surrounded by an outer optical cladding, the central core having a radius r₁ and a positive refractive index difference Δn₁ with the outer optical cladding; (ii) an intermediate cladding positioned between the central core and the outer optical cladding, the intermediate cladding having a radius r₂ and a refractive index difference Δn₂ with the outer optical cladding, wherein the refractive index difference Δn₂ is less than the refractive index difference Δn₁; and (iii) a depressed trench positioned between the intermediate cladding and the outer optical cladding, the depressed trench having a radius r₃ and a negative refractive index difference Δn₃ with the outer optical cladding; and a substantially cured primary coating surrounding the single-mode glass fiber, the substantially cured primary coating possessing (i) an in situ modulus of less than about 0.65 MPa and (ii) a glass transition temperature of less than about −50° C.; wherein, at a wavelength of 1310 nanometers, the optical fiber has a nominal mode field diameter (MFD) between 8.6 microns and 9.5 microns; wherein, at a wavelength of 1550 nanometers, the optical fiber has bending losses less than 0.15 dB/turn for a radius of curvature of 5 millimeters; and wherein the optical fiber has a cable cut-off wavelength (λ_(cc)) of 1260 nanometers or less, measured as the wavelength at which the attenuation of the LP11 mode is greater than or equal to 19.3 dB after propagation over 22 meters of fiber.
 2. An optical fiber according to claim 1, wherein the substantially cured primary coating possesses an in situ modulus of between about 0.2 MPa and 0.5 MPa.
 3. An optical fiber according to claim 1, wherein the substantially cured primary coating possesses a glass transition temperature of less than about −55° C.
 4. An optical fiber according to claim 1, wherein the primary coating achieves 50 percent of full cure at a UV dose of about 0.3 J/cm² as measured on a standard 75-micron film at standard temperature and pressure.
 5. An optical fiber according to claim 1, wherein the primary coating comprises a UV-curable urethane acrylate composition.
 6. An optical fiber according to claim 1, wherein: the surface integral of the central core (V₀₁), defined as V₀₁ = ∫₀^(r 1)Δ n(r) ⋅ 𝕕r ≈ r₁ × Δ n₁, is between 19.0×10⁻³ micron and 23.0×10⁻³ micron.
 7. An optical fiber according to claim 1, wherein: the surface integral of the depressed trench (V₀₃), defined as V₀₃ = ∫_(r 2)^(r 3)Δ n(r) ⋅ 𝕕r ≈ (r₃ − r₂) × Δ n₃, is between −55.0×10⁻³ micron and −30.0×10⁻³ micron.
 8. An optical fiber according to claim 1, wherein: the volume integral of the depressed trench (V₁₃), defined as V₁₃ = 2 ⋅ ∫_(r 2)^(r 3)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₃² − r₂²) × Δ n₃, is between −1200×10⁻³ μm² and −750×10⁻³ μm².
 9. An optical fiber according to claim 1, wherein the central core has a radius (r₁) between 3.8 microns and 4.35 microns.
 10. An optical fiber according to claim 1, wherein the intermediate cladding has a radius (r₂) between 8.5 microns and 9.7 microns.
 11. An optical fiber according to claim 1, wherein the depressed trench has a radius (r₃) between 13.5 microns and 16 microns.
 12. An optical fiber according to claim 1, wherein the central core has a refractive index difference (Δn₁) with the outer optical cladding between 4.9×10⁻³ and 5.7×10⁻³.
 13. An optical fiber according to claim 1, wherein the intermediate cladding has a refractive index difference (Δn₂) with the outer optical cladding between −0.1×10⁻³ and 0.6×10⁻³.
 14. An optical fiber according to claim 1, wherein the depressed trench has a refractive index difference (Δn₃) with the outer optical cladding between −10.0×10⁻³ and −5.0×10⁻³.
 15. An optical fiber according claim 1, wherein the optical fiber has a zero chromatic dispersion wavelength (ZDW) between 1300 nanometers and 1324 nanometers and, at the zero chromatic dispersion wavelength (ZDW), a zero chromatic dispersion slope value (ZDS) less than 0.092 ps/(nm²·km).
 16. A cable containing one or more optical fibers according to claim
 1. 17. An FTTx system comprising one or more optical fibers according to claim
 1. 18. A bend-insensitive optical fiber, comprising: a single-mode glass fiber comprising (i) a central core surrounded by an outer optical cladding, the central core having a radius r₁ and a refractive index difference Δn₁ with the outer optical cladding between about 4.9×10⁻³ and 5.7×10⁻³; (ii) an intermediate cladding positioned between the central core and the outer optical cladding, the intermediate cladding having a radius r₂ and a refractive index difference Δn₂ with the outer optical cladding between about −0.1×10⁻³ and 0.6×10⁻³; and (iii) a depressed trench positioned between the intermediate cladding and the outer optical cladding, the depressed trench having a radius r₃ and a refractive index difference Δn₃ with the outer optical cladding between about −10.0×10⁻³ and −5.0×10⁻³; and a substantially cured primary coating surrounding the single-mode glass fiber, the substantially cured primary coating possessing (i) an in situ modulus of less than about 0.65 MPa and (ii) a glass transition temperature of less than about −50° C.; wherein, at a wavelength of 1310 nanometers, the optical fiber has a nominal mode field diameter (MFD) between about 8.6 microns and 9.5 microns; wherein the optical fiber has a zero chromatic dispersion wavelength (ZDW) between 1300 nanometers and 1324 nanometers; wherein the optical fiber has a zero chromatic dispersion slope value (ZDS) at the zero chromatic dispersion wavelength less than 0.092 ps/(nm²·km); wherein, at a wavelength of 1550 nanometers, the optical fiber has bending losses less than about 3×10⁻³ dB/turn for a radius of curvature of 15 millimeters and less than about 0.15 dB/turn for a radius of curvature of 5 millimeters; wherein, at a wavelength of 1625 nanometers, the optical fiber has bending losses less than 10⁻² dB/turn for a radius of curvature of 15 millimeters and less than about 0.25 dB/turn for a radius of curvature of 5 millimeters; and wherein the optical fiber has both a standard cable cut-off wavelength (λ_(cc)) of 1260 nanometers or less and a straight cable cut-off wavelength of 1260 nanometers or less.
 19. An optical fiber according to claim 18, wherein the substantially cured primary coating possesses an in situ modulus of 0.5 MPa or less.
 20. An optical fiber according to claim 18, wherein the primary coating achieves 80 percent of full cure at a UV dose of about 0.5 J/cm² as measured on a standard 75-micron film at standard temperature and pressure.
 21. An optical fiber according to claim 18, wherein the primary coating comprises a UV-curable urethane acrylate composition.
 22. An optical fiber according to claim 18, wherein: the surface integral of the central core (V₀₁), defined as V₀₁ = ∫₀^(r 1)Δ n(r) ⋅ 𝕕r ≈ r₁ × Δ n₁, is between 19.0×10⁻³ micron and 23.0×10⁻³ micron; the surface integral of the depressed trench (V₀₃), defined as V₀₃ = ∫_(r 2)^(r 3)Δ n(r) ⋅ 𝕕r ≈ (r₃ − r₂) × Δ n₃, is between −55.0×10⁻³ micron and −30.0×10⁻³ micron; and the volume integral of the depressed trench (V₁₃), defined as V₁₃ = 2 ⋅ ∫_(r 2)^(r 3)Δ n(r) ⋅ r ⋅ 𝕕r ≈ (r₃² − r₂²) × Δ n₃, is between −1200×10⁻³ μm² and −750×10⁻³ μm².
 23. An optical fiber according to claim 18, wherein: the central core has a radius (r₁) between about 3.8 microns and 4.35 microns; the intermediate cladding has a radius (r₂) between about 8.5 microns and 9.7 microns; and the depressed trench has a radius (r₃) between about 13.5 microns and 16 microns. 